Molecular and clinical characterization of de novo and familial cases with microduplication 3q29: guidelines for copy number variation case reporting.

Microdeletions of 3q29 have previously been reported, but the postulated reciprocal microduplication has only recently been observed. Here, cases from four families, two ascertained in Toronto (Canada) and one each from Edinburgh (UK) and Leiden (Netherlands), carrying microduplications of 3q29 are presented. These families have been characterized by cytogenetic and molecular techniques, and all individuals have been further characterized with genome-wide, high density single nucleotide polymorphism (SNP) arrays run at a single centre (The Centre for Applied Genomics, Toronto). In addition to polymorphic copy-number variants (CNV), all carry duplications of 3q29 ranging in size from 1.9 to 2.4 Mb, encompassing multiple genes and defining a minimum region of overlap of about 1.6 Mb bounded by clusters of segmental duplications that is remarkably similar in location to previously reported 3q29 microdeletions. Consistent with other reports, the phenotype is variable, although developmental delay and significant ophthalmological findings were recurrent, suggesting that dosage sensitivity of genes located within 3q29 is important for eye and CNS development. We also consider CNVs found elsewhere in the genome for their contribution to the phenotype. We conclude by providing preliminary guidelines for management and anticipatory care of families with this microduplication, thereby establishing a standard for CNV reporting.

Dopamine signaling in Caenorhabditis elegans-potential for parkinsonism research.

The nematode Caenorhabditis elegans is an attractive model system for the study of many biological processes. It possesses a simple nervous system with known anatomy and connectivity, is conveniently and cheaply cultured in the laboratory, and is amenable to many genetic manipulations that are impossible in mammalian systems. The recent completion of the C. elegans genome sequence provides a rich resource of genomic and bioinformatic data to researchers in diverse fields. This organism, however, has been underexploited in the studies of many basic processes related to nervous system function, neuropsychiatric disorders and neuromuscular function. Anatomical, biochemical, behavioral, pharmacological and genetic evidence accumulated to date strongly suggests that dopamine is used as a neurotransmitter by C. elegans, and that its effects are mediated through pathway(s) that share many features with those of mammals. DNA sequence analysis reveals genes highly homologous to those encoding mammalian dopamine receptors. Probably, C. elegans has dopamine receptors that transduce environmental cues into behaviors, and these receptors pharmacologically most closely resemble the D2 family. Here we present a review of the current state of research into the dopamine system of the worm, focussing on its potential for use in the study of biological processes related to parkinsonism.

Genetic polymorphism and recombination in the subtelomeric region of chromosome 14q.

Subtelomeric regions of human chromosomes are the sites of increased meiotic recombination and have a male-to-female recombination ratio that is higher than elsewhere in the genome. We isolated two novel, polymorphic CA repeat markers from the distal part of the immunoglobulin heavy chain gene cluster, approximately 90 and 200 kb from the telomere of chromosome 14q. The 14q telomere was unambiguously located by physical mapping of telomeric YACs and Bal31 exonuclease digestion of genomic DNA. We then constructed haplotypes using genotype data from these markers and data from sCAW1 (D14S826) for use as a highly polymorphic genetic marker. Linkage analysis using the 40 pedigree CEPH reference panel and genotype data from these and other loci physically mapped to the terminal 1.5 Mb of chromosome 14q revealed an apparent increase in meiotic recombination within this region, relative to the average rate for the genome. Further, we found that recombination was higher in females than in males, indicating that the subtelomeric region of 14q differs from other human subtelomeric regions.

Molecular analysis redefines three human chromosome 14 deletions.

We have used a panel of 13 DNA markers in the distal region of chromosome 14q to characterize deletions in three patients determined cytogenetically to have a ring or terminally deleted chromosome 14. We have characterized one patient with a ring chromosome 14 [r (14) (p13q32.33)] and two with terminal deletions [del (14) (pter-->q32.3:)]. The two patients with cytogenetically identical terminal deletions of chromosome 14 were found to differ markedly when characterized with molecular markers. In one patient, none of the markers tested were deleted, indicating that the apparent terminal deletion is actually due to either an undetected interstitial deletion or a cryptic translocation event. In the other patient, the deletion was consistent with the cytogenetic observations. The deleted chromosome was shown to be of paternal origin. The long-arm breakpoint of the ring chromosome was mapped to within a 350-kb region of the immunoglobulin heavy chain gene cluster (IGH). This breakpoint was used to localize markers D14S20 and D14S23, previously thought to lie distal to IGH, to a more proximal location. The ring chromosome represents the smallest region of distal monosomy 14q yet reported.

Mapping of human immunoglobulin heavy chain variable gene segments outside the major IGH locus.

Physical mapping of the human immunoglobulin heavy chain gene cluster (IGH) on chromosome 14 has previously shown that the locus includes at least 63 variable region (VH) gene segments. Fifteen VH gene segments are located on six NotI DNA restriction fragments that are not within the mapped region of IGH. We have used human/rodent somatic cell hybrid lines to map these gene segments, as it was previously not proven that they are located in the chromosome 14 IGH locus. Four gene segments map to human chromosome 16 and two to chromosome 15. Apparently, four of the six NotI fragments, representing 11 VH gene segments, are not located within the chromosome 14 IGH locus. In addition, we have demonstrated that a YAC containing a functional human telomere, and mapping to 14qter, is located at the telomeric end of the IGH gene cluster physical map and contains at least four VH gene segments. This YAC is collinear with the existing physical map of genomic DNA. We conclude that our original physical map of IGH represents almost the entire locus on chromosome 14 and that the 11 gene segments newly mapped are not part of the functional IGH locus.

In situ hybridization to human chromosome 1 of a cDNA probe for the gene encoding the basement membrane heparan sulfate proteoglycan (HSPG).

A mouse partial cDNA clone of the heparan sulfate proteoglycan gene, an important component of basement membranes, has been mapped to human chromosome 1, band p 36.1, by in situ hybridization. No secondary sites of hybridization were observed.