Dysregulation of the fibroblast growth factor system in major depression.

In this report we describe findings that imply dysregulation of several fibroblast growth factor (FGF) system transcripts in frontal cortical regions of brains from human subjects with major depressive disorder (MDD). This altered gene expression was discovered by microarray analysis of frontal cortical tissue from MDD, bipolar, and nonpsychiatric control subjects and was verified by quantitative real-time PCR analysis and, importantly, in a separate cohort of MDD subjects. Furthermore, we show, through a separate analysis of specific serotonin reuptake inhibitor (SSRI)-treated and non-SSRI-treated MDD subjects that the observed changes in expression of FGF transcripts are not secondary to drug treatment. Rather, changes in specific FGF transcripts are attenuated by SSRIs and may thus be partially responsible for the mechanism of action of these drugs. We also make available the gene-expression profile of all of the other growth factors and growth factor receptors detected in these postmortem samples.

Influence of allele lineage on the role of the insulin minisatellite in susceptibility to type 1 diabetes.

The insulin minisatellite or variable number of tandem repeats locus (INS VNTR) is the best candidate for the type 1 diabetes mellitus (T1DM) susceptibility locus IDDM2. Small class I alleles associate with predisposition to T1DM, whereas large class III alleles associate with dominant protection. We have analysed variant repeat distribution within the minisatellite and combined this with flanking haplotypes to define five new ancestral allele lineages. Class III alleles divide into two highly diverged lineages, IIIA and IIIB, which correspond perfectly to the previously defined Protective (PH) and Very Protective (VPH) haplotypes, respectively. Class I alleles are divided into three newly defined lineages, IC+, ID+ and ID-, by a combination of variant repeat distributions and flanking haplotypes. All class I alleles are equally predisposing to T1DM except for ID- alleles which are protective when transmitted from ID-/III heterozygous fathers. Similar results have been previously reported for alleles of 42 repeats in length (allele 814) which represent a subset of the ID- lineage. Division of class ID- alleles into those of 42 repeats and those of other sizes suggested that this protective effect was a feature of all ID- alleles, irrespective of size. ID- alleles are only clearly distinguished from all other alleles by an MSPI(-) variant within IGF2 downstream of the minisatellite, suggesting that the apparent role of the minisatellite in susceptibility to T1DM may be modified by neighbouring haplotype and therefore that IDDM2 could have a multi-locus aetiology.

Allele diversity and germline mutation at the insulin minisatellite.

Previous analysis of germline mutation at highly unstable GC-rich minisatellites with continuous allele size distributions revealed similar meiotic recombinational mechanisms operating at all loci investigated. The insulin minisatellite has been studied intensively due to its associations with diabetes, polycystic ovary syndrome, obesity and birth size. Its bimodal allele size distribution in Caucasians suggests a much lower mutation rate and possible differences in the mutation process compared with highly unstable minisatellites. Mutation at the insulin minisatellite therefore was studied both indirectly from allele diversity surveys and directly by recovering de novo mutants from sperm DNA. Structural analysis of variant repeat distributions in 876 alleles identified 189 different alleles, almost all of which could be assigned to one of three very distinct lineages. Variation within a lineage was minor and due mainly to the gain or loss of one or a few repeat units. These events most probably arise by mitotic replication slippage at a frequency of perhaps 10(-3)per gamete. Sperm DNA analysis revealed a second class of mutation occurring at a frequency of approximately 2 x 10(-5)that involved highly complex intra- and inter-allelic rearrangements very similar to those seen at unstable minisatellites. These complex rearrangements were not seen in somatic DNA and are probably meiotic in origin. Minisatellite homozygosity did not reduce the frequency of these mutants in sperm. The insulin minisatellite therefore appears to evolve by two distinct processes: one involving slippage-like events and the second resulting in complex recombinational turnover of allele structure.

Human minisatellites, repeat DNA instability and meiotic recombination.

Minisatellites include some of the most variable loci in the human genome and are superb for dissecting processes of tandem repeat DNA instability. Single DNA molecule analysis has revealed different mutation processes operating in the soma and germline. Low-level somatic instability results in simple intra-allelic rearrangements. In contrast, high frequency germline instability involves complex gene conversions and is therefore recombinational in nature, almost certainly occurring at meiosis. To determine whether true meiotic crossovers occur at human minisatellites, we have used polymorphisms near the repeat array to recover recombinant DNA molecules directly from sperm DNA. Analysis of minisatellite MS32 has revealed an intense and highly localised meiotic crossover hotspot centred upstream of the array, the first example of a human hotspot defined at the molecular level. This hotspot extends into the beginning of the repeat array, resulting in unequal and equal crossovers. Array crossovers occur much less frequently than array conversions but appear to arise by a common process, most likely by alternative processing of a recombination initiation complex. The location of MS32 at the boundary of a recombination hotspot suggests that this locus has evolved as a by-product of localised meiotic recombination activity, and that minisatellites might in general mark recombinationally proficient hotspots or hot domains in the genome. Finally, sperm crossover analysis makes it possible to explore the molecular rules that govern human meiotic recombination, and to detect phenomena such as meiotic drive that could provide a possible connection between recombination and DNA sequence diversity itself.

Isolation and characterization of mouse minisatellites.

Minisatellites provide the most informative system for analyzing processes of tandem repeat turnover in humans. However, little is known about minisatellites and the mechanisms by which they mutate in other species. To this end, we have isolated and characterized 76 endogenous mouse VNTRs. Fifty-one loci have been localized on mouse chromosomes and, unlike in humans, show no clustering in proterminal regions. Sequence analysis of 25 loci revealed the majority to be authentic minisatellites with GC-rich repeat units ranging from 14 to 47 bp in length. We have further characterized 3 of the most polymorphic loci both in Mus musculus subspecies and in inbred strains by using minisatellite variant repeat mapping (MVR) by PCR to gain insight into allelic diversity and turnover processes. MVR data suggest that mouse minisatellites mutate mainly by intra-allelic nonpolar events at a rate well below 10(-3) per gamete, in contrast to the high-frequency complex meiotic gene conversion-like events seen in humans. These results may indicate a fundamental difference in mechanisms of minisatellite mutation and genome turnover between mice and humans.

Spontaneous and induced minisatellite instability.

Minisatellites provide not only the basis for DNA fingerprinting and DNA profiling but also extremely informative systems for analysing processes of tandem repeat turnover in the human genome. Minisatellite instability appears to involve distinct mutation processes in somatic and germline cells; in the germline, mutation is frequently dominated by inter-allelic conversion-like events most likely occurring at meiosis and apparently regulated by cis-acting mutation initiator elements. Attempts to define these initiators in transgenic mice have so far been thwarted by what appears to be a major human/mouse barrier to the inter-species transfer of repeat instability. Minisatellites not only show high frequency spontaneous mutation in the germline, but also appear to be very sensitive to mutation induction by ionizing radiation, both in experimentally irradiated mice and in human populations exposed following the Chernobyl disaster; the mechanisms of mutation induction by radiation remain enigmatic.