Faculty Bibliography

A method for in situ hybridization originally developed for mapping genes in the nematode, Caenorhabditis elegans has been adapted for high resolution cytological mapping of genes in the human. The probe DNAs are labelled by incorporation of biotin dUTP and the site of hybridization detected by immunofluorescence. For the accurate assignment of the hybridization signal to chromosome bands, visualized by staining with Hoechst 33258, a heterologous ribosomal DNA probe is also included in the hybridization reaction. These rDNA signals are used as fiducial markers when aligning the two fluorescent images. We demonstrate the method by assignment of the human thymocyte CD1 antigen genes to human chromosome 1q22-23.

We have studied the Burkitt's lymphoma cell line Daudi which carries the translocation t(8;14). The breakpoint of this translocation on the 14q+ chromosome occurs near to a rearranged DH-JH join, and the actual chromosome junction is a few hundred base pairs upstream of the joined DH element. The nucleotide sequence of the rearranged DH segment shows that it does not come from the previously described D cluster. Using this DH sequence as a probe we have identified two separate DH clusters. One of these is the major DH cluster and is located only 20 kb upstream of the JH segments. A pseudo-VH (probably the first VH segment) is also found approximately 98 kb from JH. A second, minor DH locus has been found which seems to be located on the distal side of the VH locus on chromosome 14, since there is little evidence for rearrangement or deletion of this locus in any B cell DNA analysed. A single VHIII subgroup gene is located within 25 kb of the newly identified DH element: it is possible that this minor locus occurs near the limit of the Igh locus.

The major sperm proteins (MSPs) are a family of closely related, small, basic proteins comprising 15% of the protein in Caenorhabditis elegans sperm. They are encoded by a multigene family of more than 50 genes, including many pseudogenes. MSP gene transcription occurs only in late primary spermatocytes. In order to study the genomic organization of transcribed MSP genes, probes specific for the 3' untranslated regions of sequenced cDNA clones were used to isolate transcribed genes from genomic libraries. These and other clones of MSP genes were located in overlapping cosmid clones by DNA fingerprinting. These cosmids were aligned with the genetic map by overlap with known genes or in-situ hybridization to chromosomes. Of 40 MSP genes identified, 37, including all those known to be transcribed, are organized into six clusters composed of 3 to 13 genes each. Within each cluster, MSP genes are not in tandem but are separated by at least several thousand bases of DNA. Pseudogenes are interspersed among functional genes. Genes with similar 3' untranslated sequences are in the same cluster. The six MSP clusters are confined to only three chromosomal loci; one on the left arm of chromosome II and two near the middle of chromosome IV. Additional sperm-specific genes are located in one cluster of MSP genes on chromosome IV. The multiplicity of MSP genes appears to be a mechanism for enhancing MSP synthesis in spermatocytes, and the loose clustering of genes could be a result of the mechanism of gene duplication or could play a role in regulation.

A novel gene from the nematode Caenorhabditis elegans was isolated by hybridization with a human calmodulin complementary DNA probe. This gene, cal-1, is present at one copy per haploid genome. In-situ hybridization of the cloned gene to metaphase chromosomes allowed us to assign it to the nematode linkage group IV. The polypeptide predicted from the sequence of this gene displays structural features of both calmodulin and troponin C.

The genes coding for the myosin heavy chain isoforms (unc-54, myo-1, myo-2 and myo-3) and the actins (act-1,2,3 and act-4) have been mapped on the embryonic metaphase chromosomes of Caenorhabditis elegans by in situ hybridization. The genes were cloned in a cosmid vector and the entire cosmid was nick translated to incorporate biotin-labeled dUTP. This produced a probe DNA complementary to a 35-45 kb length of chromosomal DNA. The hybridization signal from the cosmid probe, detected by immunofluorescence, could be easily seen by eye. The clear signals and the specific hybridization of the cosmid probes provided a faster means of mapping these single copy genes than small probes cloned in plasmid or lambda vectors. The myosin heavy chain genes are not clustered. Only unc-54 and myo-1 mapped to the same chromosome; the unc-54 locus is at the extreme right end of linkage group I and myo-1 mapped 40-50% from the left end of linkage group I. Myo-2 mapped to the X, 52-75% from the left end. The myo-3 gene mapped to the middle of linkage group V near the cluster of three actin genes (act-1,2,3). The fourth actin gene, act-4 mapped to 20-35% from the left end of X.

The site of the ribosomal gene cluster on embryonic metaphase chromosomes of Caenorhabditis elegans has been mapped by in situ hybridization using probe DNAs that have been nick-translated to incorporate biotin-labeled UTP. The hybridized probe DNA was detected by a double-layer fluorescent antibody technique. Since chromosomes from wild-type C. elegans embryos are indistinguishable, in situ hybridization was carried out with chromosomes from C. elegans strains carrying cytologically distinct translocation or duplication chromosomes in order to identify the right end of linkage group I as the site of the ribosomal genes. Chromosomes carrying a lethal mutation, let-209 I displayed smaller hybridization signals than wild-type, suggesting that these chromosomes carried a partial deficiency of the ribosomal gene cluster. A duplication of the ribosomal genes, eDp20(I;II) rescued let-209 homozygotes. Chromosomes carrying the alterations in the ribosomal genes were combined with mnT12(IV;X) to facilitate the mapping of genes in C. elegans by in situ hybridization. Linkage groups I and II are then labeled by the distinctive hybridization signals from the ribosomal probes, linkage groups IV and X are together distinguishable morphologically and linkage group V is labeled by hybridization to a 5S gene probe.

The distribution of microtubules and microtubule organizing centers in the events leading up to the establishment of the first asymmetric cleavage furrow in nematode embryos was followed using indirect immunofluorescence of antibodies to tubulin. Oocytes arrest in meiotic prophase then undergo two meiotic reduction divisions after fertilization. At both of these divisions barrel-shaped spindles were observed. Initially a single microtubule organizing center was seen adjacent to the sperm pronucleus following fertilization in Caenorhabditis elegans, but later two sperm asters were distinguished. These increased in size as the egg pronucleus migrated toward the sperm pronucleus and reached maximum size, with fascicles of microtubules extending to the cortex, once the pronuclei had become juxtaposed. The first cleavage spindle formed following rotation and migration of the juxtaposed pronuclei back toward the center of the embryo. The distribution of microtubules in a temperature-sensitive mutant that fails in both pronuclear migration and rotation was also examined. Asters in the mutant embryos at the nonpermissive temperature contained only short microtubules suggesting that the morphology of the asters is important for directing the movement of the pronuclei. In Panagrellus redivivus sperm asters were not detected by anti-tubulin staining until the female pronucleus had migrated to the centrally placed sperm pronucleus. Asters then increased in size and formed the first cleavage spindle.

Light microscopy of the mitotic chromosomes of Caenorhabditis elegans suggests that non-localized kinetochores are present, since the chromosomes appear as stiff rods 1 to 2 micrometers in length and lack any visible constriction. The holokinetic structure was confirmed by reconstructions of electron micrographs of dividing nuclei in serially sectioned embryos. In prophase the kinetochore appears as an amorphous projection approximately 0.18-0.2 micrometer in diameter in cross section and in longitudinal section it appears to be continuous along the chromatin. At prometaphase and metaphase the kinetochore is a convex plaque covering the poleward face of the chromosome and extending the length of the chromosome. In longitudinal section the kinetochore is a trilaminar structure with electron dense inner and outer layers of 0.02 micrometer, and an electron lucent middle layer of 0.03 micrometer. The inner layer is adjacent to a more electron dense region of chromatin. The kinetochore was also seen as a band extending the length of the chromosome in whole mount preparations of chromosomes stained with ethanolic phosphotungstic acid. Most gamma ray induced chromosome fragments segregate normally in embryonic mitoses, but some fragments display aberrant behavior. Similar behavior was seen in embryos carrying a genetically characterized free duplication. It is suggested that mitotic segregation of small fragments may be inefficient because the probability of attachment of microtubules to the kinetochore is proportional to kinetochore length.