Differential magnification of rDNA gene types in bobbed mutants of Drosophila melanogaster

Summary In Drosophila melanogaster a partial loss of ribosomal genes leads to the bobbed phenotype. Magnification is a heritable increase in rDNA that may occur in males carrying a deleted X chromosome with a strong bobbed phenotype. The restriction patterns of X chromosome total rDNA, insertions and spacers from magnified bobbed strains were compared with those of the original bobbed mutations. It was found that magnification modifies restriction patterns and differentially affects gene types, increasing specific genes lacking insertions (INS^-). Increases in copy number of genes with type I insertions are generally lower than the total number of INS^- genes, while type II insertion genes are not perceptibly increased. The recovery of homogeneous progeny from a single premagnified male indicates that the magnification event might take place and become stable very early in the germ line, arguing against magnification being due to extrachromosomal amplification. Additionally, some gene types increase 3.5-fold while others are eliminated, indicating that they could not result from a single unequal cross-over. These results are in good agreement with the existence of partial clustering of rDNA genes according to type, and suggest that magnification could result from local amplification of genes.     

Distinct Transcription Products of Ribosomal Genes in Two Different Tissues

MOST organisms contain multiple copies of the genes which code for ribosomal RNA (rRNA), the number varying from about 160 to 28,000 per nucleus in different eukaryotic species¹; these genes are clustered in the nucleolus. The repeating unit is a DNA sequence containing the structural genes for the 18S and 28S rRNA together with spacer DNA, only a part of which is transcribed². Ribosomal RNA is transcribed from these genes as a polycistronic precursor molecule (pre-rRNA) which contains the rRNA sequences of the larger and smaller ribosomal subunits together with some additional sequences that are discarded during the maturation to rRNA³. The multiple gene copies are identical in the ribosomal regions within the limits detectable by present methods¹, although there is some evidence that regions of non-transcribed spacer DNA vary in length and may therefore not all be identical². We have suggested that the pre-rRNA may also be heterogeneous in molecular weight⁴.     

The Green Monster Process for the Generation of Yeast Strains Carrying Multiple Gene Deletions

Phenotypes for a gene deletion are often revealed only when the mutation is tested in a particular genetic background or environmental condition^1,2. There are examples where many genes need to be deleted to unmask hidden gene functions^3,4. Despite the potential for important discoveries, genetic interactions involving three or more genes are largely unexplored. Exhaustive searches of multi-mutant interactions would be impractical due to the sheer number of possible combinations of deletions. However, studies of selected sets of genes, such as sets of paralogs with a greater a priori chance of sharing a common function, would be informative.In the yeast Saccharomyces cerevisiae, gene knockout is accomplished by replacing a gene with a selectable marker via homologous recombination. Because the number of markers is limited, methods have been developed for removing and reusing the same marker^5,6,7,8,9,10. However, sequentially engineering multiple mutations using these methods is time-consuming because the time required scales linearly with the number of deletions to be generated.Here we describe the Green Monster method for routinely engineering multiple deletions in yeast¹¹. In this method, a green fluorescent protein (GFP) reporter integrated into deletions is used to quantitatively label strains according to the number of deletions contained in each strain (Figure 1). Repeated rounds of assortment of GFP-marked deletions via yeast mating and meiosis coupled with flow-cytometric enrichment of strains carrying more of these deletions lead to the accumulation of deletions in strains (Figure 2). Performing multiple processes in parallel, with each process incorporating one or more deletions per round, reduces the time required for strain construction.The first step is to prepare haploid single-mutants termed ''ProMonsters,'' each of which carries a GFP reporter in a deleted locus and one of the ''toolkit'' loci—either Green Monster GMToolkit-a or GMToolkit-α at the can1Δ locus (Figure 3). Using strains from the yeast deletion collection¹², GFP-marked deletions can be conveniently generated by replacing the common KanMX4 cassette existing in these strains with a universal GFP-URA3 fragment. Each GMToolkit contains: either the a- or α-mating-type-specific haploid selection marker¹ and exactly one of the two markers that, when both GMToolkits are present, collectively allow for selection of diploids.The second step is to carry out the sexual cycling through which deletion loci can be combined within a single cell by the random assortment and/or meiotic recombination that accompanies each cycle of mating and sporulation.     

Genetisches Modell der autosomal-rezessiv erblichen proximalen spinalen Muskelatrophie

Proximal spinal muscular atrophy (SMA) is one of the most common autosomal recessive diseases. According to the achieved milestones, SMA is divided into 3 groups: SMA types I–III. SMA is caused by mutations in the survival motor neuron 1 (SMN1) gene, which is located on chromosome 5. Wild type alleles usually have one or two SMN1 gene copies, disease alleles may show deletions, large scale deletions, or point mutations. The proposed genetic model is based on published data on SMA types I–III. The complex genetic model of SMA allows all parameters—even those which have not been assessed so far—to be calculated. The SMN1 allele frequencies included the following: normal allele b (1 copy of SMN1): ≈?0.9527; normal allele c (2 copies of SMN1): ≈?0.0362; deletion a (0 copies of SMN1): ≈?0.0104; point mutation d (1 copy of SMN1): ≈?0.0003; large scale deletion g (0 copies of SMN1): ≈?0.0004. The result is a gene frequency of approximately 1:90 and a carrier frequency of about 1:46.     

Mapping of a Bradyrhizobium japonicum DNA Region Carrying Genes for Symbiosis and an Asymmetric Accumulation of Reiterated Sequences

Spontaneous kanamycin-sensitive derivatives were obtained from Bradyrhizobium japonicum (strain 110) carrying Tn5 insertions in symbiotic gene cluster I; the derivatives were shown to have deletions of cluster I plus flanking DNA which was indicated by the absence of different copies of the repeated sequences RSα and RSβ. The deletion endpoints were mapped using cloned wild-type DNA fragments containing RSα copies which also served as origins for overlapped cosmid cloning. The majority of the deletions resulted from recombinational fusion of two remote RSα copies. Novel types of repeated sequences (RSγ, RSδ, and RSε) occurring in 12, 10, and 4 copies per genome were detected. Seven, nine, and three copies of RSγ, RSδ, and RSε, respectively, were located near cluster I. It is concluded that the B. japonicum genome has an unusual DNA segment of >230 kilobase pairs characterized by the presence of repeated sequences and genes for symbiotic N₂ fixation.     

High‐resolution array‐CGH in patients with oculocutaneous albinism identifies new deletions of the TYR,OCA2, and SLC45A2 genes and a complex rearrangement of the OCA2 gene

Oculocutaneous albinism (OCA) is caused by mutations in six different genes, and their molecular diagnosis encompasses the search for point mutations and intragenic rearrangements. Here, we used high‐resolution array‐comparative genome hybridization (CGH) to search for rearrangements across exons, introns and regulatory sequences of four OCA genes: TYR, OCA2, TYRP1, and SLC45A2. We identified a total of ten new deletions in TYR, OCA2, and SLC45A2. A complex rearrangement of OCA2 was found in two unrelated patients. Whole‐genome sequencing showed deletion of a 184‐kb fragment (identical to a deletion previously found in Polish patients), whereby a large portion of the deleted sequence was re‐inserted after severe reshuffling into intron 1 of OCA2. The high‐resolution array‐CGH presented here is a powerful tool to detect gene rearrangements. Finally, we review all known deletions of the OCA1–4 genes reported so far in the literature and show that deletions or duplications account for 5.6% of all mutations identified in the OCA1–4 genes.     

Functional properties of the heterochromatic sequences inducing w m4 position-effect variegation in Drosophila melanogaster

In position-effect variegation euchromatic genes are brought into the vicinity of heterochromatic sequences as a result of chromosomal rearrangements. This results in the inactivation of these genes in a proportion of cells causing a variegated phenotype. Tartof et al. (1984) have shown that the flanking heterochromatin in the w ^m4 variegating rearrangement in Drosophila melanogaster is homologous to the Type I inserts found in some portions of the rDNA repeats. We have studied the functional properties of these sequences using 51 revertant chromosomes, several variant lines of w ^m4 , strong enhancer mutations of position-effect variegation and X heterochromatin deletions. Our results suggest an array of tandemly repeated sequences showing additive effects and probably subject to magnification and reduction in number. Since only 3 of the 51 revertants isolated do not show variegation if strong enhancer mutations are introduced, only a very short sequence must be essential for the induction of white gene inactivation in w ^m4 . This suggests that the heterochromatic junction itself is sufficient to initiate the variegation of an adjacent gene. Parental source as well as paternal effects on the activity of these sequences have been detected. Revertant chromosomes of w ^m4 can be found after P-directed mutagenesis in hybrid dysgenic crosses suggesting mobile genetic elements at the breakpoints of inversion w ^m4 . These results are discussed with respect to the structural basis of positioneffect variegation as well as the function of certain heterochromatic sequences.     

Evolution of a New Gene Substituting for the leuD Gene of Salmonella typhimurium: Origin and Nature of supQ and newD Mutations

The second specific enzyme in the biosynthesis of leucine, α-isopropylmalate isomerase, is coded for by two genes, leuC and leuD. Leucine auxotrophs carrying mutations in the leuD gene (including deletions of the entire leuD gene) revert to leucine prototrophy by secondary mutations at the locus supQ, which is located in the proline region of the chromosome. The mechanism of the supQ function is explained by the following model. The supQ gene and an additional gene, newD, code for two different subunits of a multimeric enzyme, whose normal function is yet to be determined. The newD gene protein is able, without genetic alterations, to form an active complex with the leuC protein, thus replacing the nonfunctional or missing leuD protein and restoring leucine prototrophy. The newD protein has, however, a higher affinity for the supQ protein than for the leuC protein; therefore, mutations in the supQ gene are needed to make sufficient amounts of the newD protein available. The following gene order has been established: gpt-proB-proA-ataA-supQ-newD. Different supQ mutations have been identified, i.e., insertion in the supQ gene, point mutations, and deletions of various extent. Some deletions remove the P22 phage attachment site ataA. Other supQ deletions are simultaneously Pro⁻, because they extend into the proA or proA and proB genes; some extend even further, i.e., into the gpt gene (guanine phosphoribosyl transferase). Mutations in the newD gene caused renewed leucine auxotrophy in leuD supQ mutant strains. One newD mutation causes a temperature-sensitive Leu⁺ phenotype. Alternate models for the supQ-newD interactions are discussed.     

A major satellite DNA of soybean is a 92-base pairs tandem repeat

We report the cloning, sequencing and analysis of the major repetitive DNA of soybean (Glycine max). The repeat, SB92, was cloned as several monomers and trimers produced by digestion with XhoI. The deduced consensus sequence of the repeat is 92 base pairs long. Genomic sequences do not fluctuate in length. Their average homology to the consensus sequence is 92%. The consensus of SB92 contains slightly degenerated homologies for several 6-cutters. Therefore, many of them generate a ladder of 92-bp oligomers. The distribution of bands seems to be random, but the occurrence of sites for different 6-cutters varies widely. There is no obvious correlation between the sequences of the neighboring units of SB92 in cloned trimers. Also, there are none of the internal repetitive blocks reported for many satellite DNAs from other species. The SB92 repeat makes up 0.7% of total soybean DNA. This is equivalent to 8×10⁴ copies, or 7 megabases. The repeat is organized in giant tandem blocks over 1 Mb in length, and there are fewer blocks than chromosomes. The polymorphism of these blocks is extremely high. The SB92 repeat is present in identical arrangement and number of copies in the ancestral subspecies Glycine soja. There are 10 times fewer copies of the repeat in a related species Vigna unguiculata (cowpea), and no homologies in several other more distant leguminous plants studied.     

A high-throughput method for the detection of homoeologous gene deletions in hexaploid wheat

Background  

Mutational inactivation of plant genes is an essential tool in gene function studies. Plants with inactivated or deleted genes may also be exploited for crop improvement if such mutations/deletions produce a desirable agronomical and/or quality phenotype. However, the use of mutational gene inactivation/deletion has been impeded in polyploid plant species by genetic redundancy, as polyploids contain multiple copies of the same genes (homoeologous genes) encoded by each of the ancestral genomes. Similar to many other crop plants, bread wheat (Triticum aestivum L.) is polyploid; specifically allohexaploid possessing three progenitor genomes designated as 'A', 'B', and 'D'. Recently modified TILLING protocols have been developed specifically for mutation detection in wheat. Whilst extremely powerful in detecting single nucleotide changes and small deletions, these methods are not suitable for detecting whole gene deletions. Therefore, high-throughput methods for screening of candidate homoeologous gene deletions are needed for application to wheat populations generated by the use of certain mutagenic agents (e.g. heavy ion irradiation) that frequently generate whole-gene deletions.     

Pharmacological analysis of heartbeat in Drosophila

Analysis of the mechanisms underlying cardiac excitability can be faciliated greatly by mutations that disrupt ion channels and receptors involved in this excitability. With an extensive repertoire of such mutations, Drosophila provides the best available genetic model for these studies. However, the use of Drosophila for this purpose has been severely handicapped by lack of a suitable preparation of heart and a complete lack of knowledge about the ionic currents that underlie its excitability. We describe a simple preparation to measure heartbeat in Drosophila. This preparation was used to ask if heartbeat in Drosophila is myogenic in origin, and to determine the types of ion channels involved in influencing the heart rate. Tetrodotoxin, even at a high concentration of 40 μM, did not affect heart rate, indicating that heartbeat may be myogenic in origin and that it may not be determined by Na⁺ channels. Heart rate was affected by PN200–110, verapamil, and diltiazem, which block vertebrate L-type Ca²⁺ channels. Thus, L-type channels, which contribute to the prolonged plateau of action potentials in vertebrate heart, may play a role in Drosophila cardiac excitability. It also suggests that Drosophila heart is subject to a similar intervention by organic Ca²⁺ channel blockers as the vertebrate heart. A role for K⁺ currents in the function of Drosophila heart was suggested by an effect of tetraethylammonium, which blocks all the four identified K⁺ currents in the larval body wall muscles, and quinidine, which blocks the delayed rectifier K⁺ current in these muscles. The preparation described here also provides an extremely simple method for identifying mutations that affect heart rate. Such mutations and pharmacological agents will be very useful for analyzing molecular components of cardiac excitability in Drosophila. © 1995 John Wiley & Sons, Inc.     

Mutations in the VNTR of the carboxyl-ester lipase gene (CEL) are a rare cause of monogenic diabetes

We have previously shown that heterozygous single-base deletions in the carboxyl-ester lipase (CEL) gene cause exocrine and endocrine pancreatic dysfunction in two multigenerational families. These deletions were found in the first and fourth repeats of a variable number of tandem repeats (VNTR), which has proven challenging to sequence due to high GC-content and considerable length variation. We have therefore developed a screening method consisting of a multiplex PCR followed by fragment analysis. The method detected putative disease-causing insertions and deletions in the proximal repeats of the VNTR, and determined the VNTR-length of each allele. When blindly testing 56 members of the two families with known single-base deletions in the CEL VNTR, the method correctly assessed the mutation carriers. Screening of 241 probands from suspected maturity-onset diabetes of the young (MODY) families negative for mutations in known MODY genes (95 individuals from Denmark and 146 individuals from UK) revealed no deletions in the proximal repeats of the CEL VNTR. However, we found one Danish patient with a short, novel CEL allele containing only three VNTR repeats (normal range 7–23 in healthy controls). This allele co-segregated with diabetes or impaired glucose tolerance in the patient’s family as six of seven mutation carriers were affected. We also identified individuals who had three copies of a complete CEL VNTR. In conclusion, the CEL gene is highly polymorphic, but mutations in CEL are likely to be a rare cause of monogenic diabetes.     

A preliminary genetic analysis of TE146, a very large transposing element of Drosophila melanogaster

TE146 is a transposing element (TE) consisting of six polytene chromosome bands that has inserted into the no-ocelli (noc 250) locus. This member of Ising's TE family carries two copies of the white and roughest loci. TE146 is lost from noc with a spontaneous frequency of approximately 1 in 22000 chromosomes. All spontaneous losses are accompanied by the reversion of the noc mutation associated with the TE. The TE is associated with fold-back (FB) sequences. The losses of TE146 retain fold-back homology at noc. Of 26 -ray-induced losses of TE146, 16 are gross deletions, removing loci neighboring noc and ten are not. The non-deleted -ray-induced losses are either noc ^– and rst ⁺ or noc ⁺ and rst ^–. The white⁺ genes of TE146 are dosage compensated since w/Y; TE146/+ and w/w; TE146/+ flies are sexually dimorphic for eye color. These w ⁺ genes are also suppressed by zeste since z w; TE146/+ flies have zeste-colored eyes.     

DNA insertion mutagenesis in a Pseudomonas aeruginosa R plasmid.

The transposons Tn501 and Tn7 were used to obtain transfer-deficient (Tra^?) and carbenicillin-sensitive (Cb^s) mutants of the narrow-host-range R plasmid R91-5 of Pseudomonas aeruginosa. In cells that are harboring R91-5 together with an unrelated transposon-donor plasmid and that have undergone 50–75 cell divisions (established donors), both transposons induced a very high frequency (87–93%) of mutations affecting Tra and Cb^r. However, when transconjugants inheriting the transposon are immediately assayed for mutations (recent transposition events) there is a marked difference in the yield of mutants. Although both transposons generated Cb^s mutants at the same frequency (0.1%), Tn7 induced Tra^? mutants at a frequency of 59% as compared to 0.23% by Tn501. Some Tra^? mutants induced by both transposons were leaky but retransfer tests showed that this was not due to reversion. Both transposons showed considerable specificity when mutations affecting transfer-related functions such as sensitivity to donor-specific phage, inhibition of the replication of phage G101, and entry exclusion were compared. Thirty-seven percent of the Tra^? mutants induced by Tn501 were also Cb^s. These double mutants were leaky with respect to all the properties tested and selection for Cb^r revertants restored Tra⁺ simultaneously. A number of hypotheses were considered as explanations including the possibility that tra (transfer genes) and bla (the β-lactamase gene for carbenicillin resistance) are closely linked in R91-5, that tra formed a number of operons with one of them encompassing bla, and the possible creation of a new promoter in the bla gene which impeded tra expression. Both transposons generated a high frequency (81–86%) of deletions of the bla gene as judged by nonrevertibility.     

Mutational mechanisms of Williams-Beuren syndrome deletions

Williams-Beuren syndrome (WBS) is a segmental aneusomy syndrome that results from a heterozygous deletion of contiguous genes at 7q11.23. Three large region-specific low-copy repeat elements (LCRs), composed of different blocks (A, B, and C), flank the WBS deletion interval and are thought to predispose to misalignment and unequal crossing-over, causing the deletions. In this study, we have determined the exact deletion size and LCR copy number in 74 patients with WBS, as well as precisely defined deletion breakpoints in 30 of them, using LCR-specific nucleotide differences. Most patients (95%) exhibit a 1.55-Mb deletion caused by recombination between centromeric and medial block B copies, which share approximately 99.6% sequence identity along 105-143 kb. In these cases, deletion breakpoints were mapped at several sites within the recombinant block B, with a cluster (>27%) occurring at a 12 kb region within the GTF2I/GTF2IP1 gene. Almost one-third (28%) of the transmitting progenitors were found to be heterozygous for an inversion between centromeric and telomeric LCRs. All deletion breakpoints in the patients with the inversion occurred in the distal 38-kb block B region only present in the telomeric and medial copies. Finally, only four patients (5%) displayed a larger deletion ( approximately 1.84 Mb) caused by recombination between centromeric and medial block A copies. We propose models for the specific pairing and precise aberrant recombination leading to each of the different germline rearrangements that occur in this region, including inversions and deletions associated with WBS. Chromosomal instability at 7q11.23 is directly related to the genomic structure of the region.     

Patterns of reversion to bobbed condition of magnified bobbed loci in D. melanogaster.

Summary The number of genes coding for the ribosomal RNA (rDNA) can increase in D. melanogaster by means of a process called magnification. In this way, a partial deletion in this locus, termed bobbed, can reach a wild type condition. A newly magnified locus, in turn, reverts to a deficient bobbed condition if it is kept in a phenotypically wild type genotype for several generations. We studied bobbed loci at different magnification steps, analysing their behaviour through the reversion process and the way they carry out a second round of magnification. Results based on the analysis of the reversion process led to the conclusion that magnification consists of a progressive integration into the bobbed locus of free rDNA copies. Moreover, evidence is supplied that the extent of this integration affects the way a reverted locus goes through a second magnification cycle. The extensive characterization of reverted bobbed loci lends substantial support to the extra copies model of rDNA magnification.     

Mutational Profiling of Malignant Mesothelioma Revealed Potential Therapeutic Targets in EGFR and NRAS

Pemetrexed and platinum (PP) combination chemotherapy is the current standard first-line therapy for treatment of malignant mesothelioma (MM). However, a useful predictive biomarker for PP therapy is yet to be found. Here, we performed targeted exome sequencing to profile somatic mutations and copy number variations in 12 MM patients treated with PP therapy. We identified 187 somatic mutations in 12 patients (65 synonymous, 102 missense, 2 nonsense, 5 splice site, and 13 small coding insertions/deletions). We identified somatic mutations in 23 genes including BAP1, TP53, NRAS, and EGFR. Interestingly, rare NRAS p.Q61K and EGFR exon 19 deletions were observed in 2 patients. We also found somatic chromosomal copy number deletions in CDKN2A and CDKN2B genes. Genetic alteration related to response after PP therapy was not found. Somatic mutation profiling in MM patients receiving PP therapy revealed genetic alterations in potential therapeutic targets such as NRAS and EGFR. No alterations in genes with potential predictive role for PP therapy were found.     

Analysis of Pax6 Contiguous Gene Deletions in the Mouse,Mus musculus,Identifies Regions Distinct from Pax6 Responsible for Extreme Small-Eye and Belly-Spotting Phenotypes

In the mouse Pax6 function is critical in a dose-dependent manner for proper eye development. Pax6 contiguous gene deletions were shown to be homozygous lethal at an early embryonic stage. Heterozygotes express belly spotting and extreme microphthalmia. The eye phenotype is more severe than in heterozygous Pax6 intragenic null mutants, raising the possibility that deletions are functionally different from intragenic null mutations or that a region distinct from Pax6 included in the deletions affects eye phenotype. We recovered and identified the exact regions deleted in three new Pax6 deletions. All are homozygous lethal at an early embryonic stage. None express belly spotting. One expresses extreme microphthalmia and two express the milder eye phenotype similar to Pax6 intragenic null mutants. Analysis of Pax6 expression levels and the major isoforms excluded the hypothesis that the deletions expressing extreme microphthalmia are directly due to the action of Pax6 and functionally different from intragenic null mutations. A region distinct from Pax6 containing eight genes was identified for belly spotting. A second region containing one gene (Rcn1) was identified for the extreme microphthalmia phenotype. Rcn1 is a Ca⁺²-binding protein, resident in the endoplasmic reticulum, participates in the secretory pathway and expressed in the eye. Our results suggest that deletion of Rcn1 directly or indirectly contributes to the eye phenotype in Pax6 contiguous gene deletions.CONTIGUOUS gene deletions account for a significant portion of human genetic syndromes. The application of fluorescence in situ hybridization (FISH) cytogenetics and array comparative genome hybridization (array-CGH) technologies have enabled more accurate localization of deletion breakpoints. This deletion information combined with the annotation of the human genome structure provides critical information to identify genes responsible for particular phenotypes associated with a syndrome. For example, deletions of the 11p11p12 and 11p13 regions on the short arm of human chromosome (Chr) 11 have been identified in the Potocki–Shaffer syndrome (Shaffer et al. 1993; Bartsch et al. 1996; Potocki and Shaffer 1996) and the Wilm''s tumor- aniridia- genitourinary abnormalities- mental retardation (WAGR) syndrome (Riccardi et al. 1978; Francke et al. 1979; Hittner et al. 1979; Fryns et al. 1981), respectively. Deletion analyses were important in identifying genes associated with clinical features of the syndromes: EXT2 for multiple exostoses and ALX4 for parietal foramina in Potocki–Shaffer syndrome (Ligon et al. 1998; Wu et al. 2000; Wakui et al. 2005), WT1 for Wilm''s tumor, and PAX6 for aniridia in WAGR syndrome (van Heyningen et al. 1985; Glaser et al. 1986, 1992; Fantes et al. 1992). Deletion analyses have also defined the extent of the deleted region in patients with combined Potocki–Shaffer and WAGR syndromes (McGaughran et al. 1995; Brémond-Gignac et al. 2005) as well as microdeletions 3′ to PAX6, which prevent expression of PAX6 and cause aniridia (Lauderdale et al. 2000; D''elia et al. 2007; Davis et al. 2008).The mouse Chr 2 region homologous to the human WAGR region contains the genes Wt1, Rcn1, Pax6, and Elp4. An extensive allelic series at Pax6 has been identified (Bult et al. 2008). Heterozygote Pax6 intragenic null mutants express microphthalmia, iris anomalies, corneal opacities, lens opacities, and lens-corneal adhesions. Homozygotes are anophthalmic and die shortly after birth (Roberts 1967; Hogan et al. 1986). Five deletions in the region have been identified: Pax6^Sey-Dey, Pax6^Sey-H, Pax6^Sey-2H, Pax6^Sey-3H, Pax6^Sey-4H of which two, Pax6^Sey-H (Hogan et al. 1986; Kent et al. 1997; Kleinjan et al. 2002; Webb et al. 2008) and Pax6^Sey-Dey (Theiler et al. 1978; Hogan et al. 1987; Glaser et al. 1990), have been well characterized. Heterozygotes for both deletions express belly spotting and a more extreme eye phenotype than that observed for heterozygotes of intragenic Pax6 null mutations. Homozygotes for both deletions are lethal at an early embryonic stage.We were particularly interested in the extreme eye phenotype associated with the Pax6 deletions and considered two alternative hypotheses. Either Pax6 deletions are functionally different from Pax6 intragenic null mutations or deletion of a region linked to but distinct from the Pax6 structural gene affects the eye phenotype.In the present study we identify three new deletions encompassing the Pax6 region of the mouse. They have been assigned the mutant allele symbols Del(2)Pax6^11Neu/1Neu, Del(2)Pax6^12Neu/2Neu, and Del(2)Pax6^13Neu/3Neu and will be referred to throughout this publication as Pax6^11Neu, Pax6^12Neu, and Pax6^13Neu, respectively. All three deletions are homozygous lethal at an early embryonic stage. The deletions differentiate for the extent of the eye abnormality expressed: Pax6^11Neu heterozygotes express extreme microphthalmia similar to that observed in the Pax6^Sey-Dey and Pax6^Sey-H deletions. Pax6^12Neu and Pax6^13Neu heterozygotes express the milder eye abnormality seen in heterozygous intragenic null mutants. For all three deletions, heterozygotes do not express belly spotting. Genetic, phenotypic, and molecular characterization of the deletions allowed us to identify regions associated with the array of phenotypes in these contiguous gene deletions.