John C. Maule

Hsp90 selectively modulates phenotype in vertebrate development.

Compromised heat shock protein 90 (Hsp90) function reveals cryptic phenotypes in flies and plants. These observations were interpreted to suggest that this molecular stress-response chaperone has a capacity to buffer underlying genetic variation. Conversely, the protective role of Hsp90 could account for the variable penetrance or severity of some heritable developmental malformations in vertebrates. Using zebrafish as a model, we defined Hsp90 inhibitor levels that did not induce a heat shock response or perturb phenotype in wild-type strains. Under these conditions the severity of the recessive eye phenotype in sunrise, caused by a pax6b mutation, was increased, while in dreumes, caused by a sufu mutation, it was decreased. In another strain, a previously unobserved spectrum of severe structural eye malformations, reminiscent of anophthalmia, microphthalmia, and nanophthalmia complex in humans, was uncovered by this limited inhibition of Hsp90 function. Inbreeding of offspring from selected unaffected carrier parents led to significantly elevated malformation frequencies and revealed the oligogenic nature of this phenotype. Unlike in Drosophila, Hsp90 inhibition can decrease developmental stability in zebrafish, as indicated by increased asymmetric presentation of anophthalmia, microphthalmia, and nanophthalmia and sunrise phenotypes. Analysis of the sunrise pax6b mutation suggests a molecular mechanism for the buffering of mutations by Hsp90. The zebrafish studies imply that mild perturbation of Hsp90 function at critical developmental stages may underpin the variable penetrance and expressivity of many developmental anomalies where the interaction between genotype and environment plays a major role.

Cadherin-Mediated Differential Cell Adhesion Controls Slow Muscle Cell Migration in the Developing Zebrafish Myotome

Slow-twitch muscle fibers of the zebrafish myotome undergo a unique set of morphogenetic cell movements. During embryogenesis, slow-twitch muscle derives from the adaxial cells, a layer of paraxial mesoderm that differentiates medially within the myotome, immediately adjacent to the notochord. Subsequently, slow-twitch muscle cells migrate through the entire myotome, coming to lie at its most lateral surface. Here we examine the cellular and molecular basis for slow-twitch muscle cell migration. We show that slow-twitch muscle cell morphogenesis is marked by behaviors typical of cells influenced by differential cell adhesion. Dynamic and reciprocal waves of N-cadherin and M-cadherin expression within the myotome, which correlate precisely with cell migration, generate differential adhesive environments that drive slow-twitch muscle cell migration through the myotome. Removing or altering the expression of either protein within the myotome perturbs migration. These results provide a definitive example of homophilic cell adhesion shaping cellular behavior during vertebrate development.

Pulsed‐field Gel Electrophoresis

Pulsed-field gel electrophoresis (PFGE) was originally developed as a technique for providing electrphoretic karyotypes of micro-organisms. Since then the technique has evolved and diversified in many new directions. This review traces the evolution of PFGE, summarizes our understanding of its theoretical basis, and provides a comprehensive description of the methodology. Established and novel application are explored and the reader, is provided with an extensive list of references.

A fission yeast chromosome can replicate autonomously in mouse cells

To test the functional capacity of a fission yeast chromosome in mouse cells, a strain of the fission yeast Schizosaccharomyces pombe, ED628 Int5, was constructed. A plasmid bearing the SV2NEO gene, which can confer G418 resistance to mouse cells, was integrated at the ura4 locus on S. pombe chromosome III. S. pombe Int5 chromosomes were introduced into mouse C127 cells by PEG-facilitated protoplast fusion. Here we describe two independent G418-resistant cell lines with distinct growth characteristics, F1.1 and F7.1, and examine the structure of material derived from S. pombe Int5 chromosome III in these lines. F1.1 is shown to contain a single rearranged block of chromatin from S. pombe chromosome III integrated into a mouse chromosome, maintained in the absence of selection. In contrast, the data for F7.1 are consistent with the presence of linear, unintegrated copies of S. pombe chromosome III, which are apparently intact and maintained in an unstable but autonomous state. The unstable maintenance of this chromosome may be due to defective centromere function leading to missegregation at mitosis or to over- or underreplication.

CpG islands surround a DNA segment located between translocation breakpoints associated with genitourinary dysplasia and aniridia

We have isolated a DNA segment absent from all the constitutionally deleted chromosomes 11 of our patients with Wilms tumor. This marker separates two balanced translocations that break in band 11p13: the distal one associated with aniridia (AN2), and the proximal one with genitourinary dysplasia (GUD). The GUD breakpoint maps within the smallest region of overlap (SRO) for the Wilms tumor (WT) gene locus, thus strengthening the previous suggestion of an association between Wilms tumor and other abnormalities of the genitourinary system. The 11p13 translocation breakpoint associated with T-cell acute lymphatic leukemia (T-ALL) is centromeric to the SRO and separated from the WT locus by at least one known gene. This region of the human genome (11p13) is rich in CpG islands that potentially identify genes, some of which may be involved in the various phenotypes associated with the WAGR syndrome. This is consistent with the proposition that the majority of human genes are in G-negative bands.

A long-range restriction map across 3 Mb of the chromosome 11 breakpoint region of a translocation linked to schizophrenia: localization of the breakpoint and the search for neighbouring genes

A balanced t(1;11)(q42.1;q14.3) translocation segregates with schizophrenia and related mental illness in a single large Scottish pedigree. We have constructed a long-range restriction map covering at least 3 Mb of the chromosome 11 breakpoint region and conducted searches for genes whose expression could be altered by the translocation, resulting in schizophrenia. Novel transcribed sequences of unknown function clustered around putative CpG islands, located approximately 500 kb and 700 kb above the breakpoint, represent the only evidence to date for expressed genes within the mapped region.

Novel transcribed sequences neighbouring a translocation breakpoint associated with schizophrenia

A 1.3Mb chromosome 11-specific yeast artificial chromosome (YAC) that spans a t(1;11) translocation breakpoint associated with major psychosis has been used to enrich cDNAs that are encoded within it and expressed in the human foetal brain. Database analysis of the selected fragments led to the identification of 54 clones matching alpha-tubulin, 4 fragments matching two anonymous human expressed sequence tags (ESTs) and 8 fragments giving no database matches. The clones matching alpha-tubulin led to the identification of a novel alpha-tubulin locus located approximately 250 kb proximal to the translocation breakpoint. Extensive sequence and expression analysis of this locus suggests that this is a processed pseudogene, although a long open reading frame is maintained and the possibility that an abnormally acting protein may be expressed in a highly tissue or developmental specific manner cannot be discounted. The novel cDNA fragments map up to 700 kb proximal to the translocation breakpoint and are associated with potential CpG islands. Reverse transcriptase polymerase chain reaction (RT-PCR) expression analysis and high resolution genomic mapping suggest that they may comprise up to three novel genes. No major disruption of the identified fragments could be detected in the genomic DNA of translocation carriers. The psychosis associated with this translocation may therefore be due to position effects on the transcription of these genes or an involvement of translocated chromosome 1 sequences.

SEMICONDUCTOR-CONTROLLED CONTOUR-CLAMPED HOMOGENEOUS ELECTRIC FIELD APPARATUS

The design and construction of a transistor-driven hexagonal contour-clamped homogeneous electric field (CHEF) apparatus is discussed in detail. The addition of computer control of pulsed-field timings and experiment duration gives rise to an efficient electrophoresis tool designed to achieve separation of DNA molecules in different size groupings. In particular, pulse time regimes which lead to the monotonic separation of DNA molecules ranging from 90 kbp to over a megabase pair are demonstrated. Theoretical treatment of electric field clamping with transistor-driven multiple electrodes is supported by measurements and by the actual performance of electrophoretic separation of yeast chromosomes. The large sample capacity of gels run in this apparatus coupled with the modest power requirements necessary to provide a homogeneous electric field offer significant advantages over earlier CHEF designs.

Long-range structure of H-ras 1-selected transgenomes

We have used chromosome-mediated gene transfer (CMGT) and whole cell fusion to derive human-mouse hybrid cells carrying reduced human chromosomes 11, by selecting for expression of the transforming H-ras 1 oncogene. To realize the full potential of these somatic cell genetic techniques as resources for enriched DNA probe isolation and the fine structure mapping of chromosomes, the nature of any molecular rearrangements that may accompany the process of DNA transfer must be understood. We have analyzed the long-range structure of our transgenomes by pulsed field gel electrophoresis (PFGE) and show here that, whereas during cell fusion several megabase pairs (Mb) of DNA can be transferred intact, multiple rearrangements of DNA accompany CMGT even in transgenomes where other methods of analysis gave no indication of such molecular scrambling.

Molecular Analysis of the Aniridia — Wilms’ Tumor Syndrome

Wilms’ tumor is an embryonic nephroblastoma which occurs at a frequency of 1/10,000 children and usually manifests within the first three years of life. 1/50 of the individuals with Wilms’ tumor also suffers from congenital aniridia (no iris), a condition which ultimately leads to blindness if untreated. Conversely 1/2 to 1/3 children with sporadic aniridia will go on to develop Wilms’ tumor. Individuals with both these conditions are almost invariably mentally retarded and will often have other genitourinary abnormalities such as ambiguous genitalia, gonadoblastoma and a variety of kidney defects. This syndrome, the WAGR syndrome (Wilms’ tumor, Aniridia, Genitourinary abnormalities, Mental Retardation) is associated frequently with a constitutional deletion of the short arm of one chromosome 11 which always involves the distal part of band 11p13 (Riccardi et al., 1978).