A genetic perspective on myopia.

Myopia is a refractive error of the eye that has a significant socioeconomic impact due to its increasing prevalence and the fact that it causes visual impairment. Its aetiology is complex and is likely to involve the interaction of environmental and genetic influences. Tight environmental influence is exemplified by defocus-induced myopia produced in animal models, while genetic factors predominate in familial occurrence of myopia with a Mendelian inheritance pattern. The involvement of numerous mediators, such as cytokines, neurotransmitters and transcription factors, in myopia development has been indicated through various lines of investigation, particular interest focussing on scleral extracellular matrix proteins and developmental genes of the eye. As high-throughput technology for large-scale genotyping and RNA expression analysis enters the field of myopia research, a productive avenue will open up for deciphering the aetiological heterogeneity of myopia and the biological pathways underlying its development.

PCR-induced sequence alterations hamper the typing of prehistoric bone samples for diagnostic achondroplasia mutations.

Achondroplasia (ACH) is a skeletal disorder (MIM100800) with an autosomal dominant Mendelian inheritance and complete penetrance. Here we report the screening of ancient bone samples for diagnostic ACH mutations. The diagnostic G-->A transition in the FGFR3 gene at cDNA position 1138 was detected in cloned polymerase chain reaction (PCR) products obtained from the dry mummy of the Semerchet tomb, Egypt (first dynasty, approximately 4,890-5,050 BP [before present]), and from an individual from Kirchheim, Germany (Merovingian period, approximately 1,300-1,500 BP), both of which had short stature. However, these mutations were also reproducibly observed in four ancient control samples from phenotypically healthy individuals (false-positives), rendering the reliable molecular typing of ancient bones for ACH impossible. The treatment of a false-positive DNA extract with uracil N-glycosylase (UNG) to minimize type 2 transitions (G-->A/C-->T) did not reduce the frequency of the false-positive diagnostic ACH mutations. Recently, it was suggested that ancient DNA extracts may induce mutations under PCR. Contemporary human template DNA from a phenotypically healthy individual was therefore spiked with an ancient DNA extract from a cave bear. Again, sequences with the diagnostic G-->A transition in the FGFR3 gene were observed, and it is likely that the false-positive G-->A transitions result from errors introduced during the PCR reaction. Amplifications in the presence of MnCl(2) indicate that position 1138 of the FGFR3 gene is particularly sensitive for mutations. Our data are in line with previously published results on the occurrence of nonrandom mutations in PCR products of contemporary human mitochondrial HVRI template DNA spiked with ancient DNA extracts.

CNGA3 mutations in hereditary cone photoreceptor disorders.

We recently showed that mutations in the CNGA3 gene encoding the alpha-subunit of the cone photoreceptor cGMP-gated channel cause autosomal recessive complete achromatopsia linked to chromosome 2q11. We now report the results of a first comprehensive screening for CNGA3 mutations in a cohort of 258 additional independent families with hereditary cone photoreceptor disorders. CNGA3 mutations were detected not only in patients with the complete form of achromatopsia but also in incomplete achromats with residual cone photoreceptor function and (rarely) in patients with evidence for severe progressive cone dystrophy. In total, mutations were identified in 53 independent families comprising 38 new CNGA3 mutations, in addition to the 8 mutations reported elsewhere. Apparently, both mutant alleles were identified in 47 families, including 16 families with presumed homozygous mutations and 31 families with two heterozygous mutations. Single heterozygous mutations were identified in six additional families. The majority of all known CNGA3 mutations (39/46) are amino acid substitutions compared with only four stop-codon mutations, two 1-bp insertions and one 3-bp in-frame deletion. The missense mutations mostly affect amino acids conserved among the members of the cyclic nucleotide gated (CNG) channel family and cluster at the cytoplasmic face of transmembrane domains (TM) S1 and S2, in TM S4, and in the cGMP-binding domain. Several mutations were identified recurrently (e.g., R277C, R283W, R436W, and F547L). These four mutations account for 41.8% of all detected mutant CNGA3 alleles. Haplotype analysis suggests that the R436W and F547L mutant alleles have multiple origins, whereas we found evidence that the R283W alleles, which are particularly frequent among patients from Scandinavia and northern Italy, have a common origin.

Case populations must match the respective disease model: Genotype diversity causes linkage disequilibrium mapping failure in monogenic disorders.

Traditional linkage analysis in large families is the most promising approach for mapping disease genes of monogenic heritable disorders when the number of informative meioses is sufficient. With rare diseases, however, the low availability of informative pedigrees poses a significant limitation. As an adjunct to family linkage methods, association studies based on the investigation of individual haplotypes from a number of unrelated patients (i.e. linkage disequilibrium analysis) have recently been employed in mapping hereditary disease loci. However, such haplotype analysis is hampered by a number of effects that influence statistical evaluation, e.g. i) population history and size, ii) allele and haplotype frequencies in the respective population(s), iii) heterogeneous mutation and natural selection processes, and iv) small sample sizes of patient groups. The purpose of the present study was to determine the utility and limitations of haplotype-based genetic mapping in estimating the location of the NYX gene, which has recently been identified as the causative gene for a rare inherited retinal disorder known as the complete type of X-linked congenital stationary night blindness (CSNB1). For this purpose we recapitulated haplotypes and tested for linkage disequilibrium in 20 unrelated male CSNB1 patients from three European populations and 44 healthy individuals. All subjects were genotyped for 17 polymorphic microsatellite loci covering the Xp11.4 region with an average marker density of approximately 0.29 cM. We found that a precise model to describe mutations at loci that erroneously break up linkage is highly required, and that the case population must match the respective disease model.

Intrapopulational relationships in ancient societies: a multidisciplinary study.

Kinship determination is one of the major challenges for the anthropologist studying graveyard populations. Traditional techniques based on morphological comparisons of bone remains are limited. However, recent methods which generate and characterise DNA sequences derived from bones bear the possibility for a more accurate analysis. Extraction and characterisation of authentic nucleic acids was performed on a number of individuals from the early Medieval graveyard of Neresheim, South Germany. From this cemetery a total of 38 skeletal remains of individuals buried between 450 and 700 AD were examined using PCR-based methods. Comparisons were made using four human-specific short tandem repeat loci and the X/Y-specific amelogenin sex test. Twenty-eight of the approximately 1,500-year-old individuals yielded alleles in at least one of the polymorphic nuclear loci HumCD4, HumFES, HumTH01, HumVWA, and the sex test. These along with a 96 bp DNA variant previously unknown in recent CD4 contexts, and supporting evidence from anthropology and archaeology were used for defining one parental and one filial generation in each of three multiple burials (Ne 2, Ne 9 and Ne 78) in the cemetery.

Cremation practices and the survival of ancient DNA: burnt bone analyses via RAPD-mediated PCR.

Numerous burial rites have been developed in different time periods of human cultural evolution. One of the most interesting burial practices was the ritual cremation of human bodies. Due to the respective cultural and religious background, brand graves are known where human remains had been buried together with burnt bones of animal origin. To date, burnt bone samples have been refractory to PCR-mediated amplification. D/L values of aspartic acid far greater than 80 x 10(-3) were measured in the samples thus indicating the presence of severely nicked and fragmented nucleic acids. In order to differentiate between burial gift of animal origin and burnt human specimens we established a highly sensitive protocol that addresses all the shortcomings connected to degraded ancient DNA. With the novel procedure it was possible to classify 4 specimens ranging from 2,000-5,000 BP on the basis of mitochondrial DNA sequences.

Physical mapping and exclusion of GPR34 as the causative gene for congenital stationary night blindness type 1.

X-linked congenital stationary night blindness (CSNB) is a nonprogressive retinal disorder characterized by impaired night vision, variably involving high myopia, nystagmus, decreased visual acuity, and strabismus. Linkage studies have identified two distinct loci for X-linked CSNB1 and CSNB2 on the short arm of chromosome X. The gene mutated in families displaying the "incomplete phenotype" of CSNB (i.e., CSNB2) has recently been identified. To identify novel candidate genes for the "complete form" of CSNB (i.e., CSNB1) we screened the physically vast region Xp11.3-Xp11.4 for cDNA sequences. This led us to identify and map the G protein coupled receptor (GPCR) gene GPR34 to Xp11.4 within 650 kb of the marker DXS993. Deletion screening via Southern blotting and direct sequencing of GPR34 revealed no mutations in 19 unrelated men with CSNB1, excluding a causal role in the disease. However, because of its expression in retinal and neural tissue and the involvement of GPCRs in transmembrane signal transduction, GPR34 remains a putative candidate gene for a number of ocular diseases which also map to the Xp11.4 region.

Mutations in the CNGB3 gene encoding the beta-subunit of the cone photoreceptor cGMP-gated channel are responsible for achromatopsia (ACHM3) linked to chromosome 8q21.

Achromatopsia is an autosomal recessive disorder featuring total colour blindness, photophobia, reduced visual acuity and nystagmus. While mutations in the CNGA3 gene on chromosome 2q11 are responsible for achromatopsia in a subset of patients, previous linkage studies have localized another achromatopsia locus, ACHM3, on chromosome 8q21. Using achromatopsia families in which CNGA3 mutations have been excluded, we refined the ACHM3 locus to a 3.7 cM region enclosed by markers D8S1838 and D8S273. Two yeast artificial chromosome (YAC) contigs covering nearly the entire ACHM3 interval were constructed. Database searches with YAC content sequences identified two overlapping high throughput genomic sequencing phase (HTGS) entries which contained sequences homologous to the murine cng6 gene encoding the putative beta-subunit of the cone photoreceptor cGMP-gated channel. Using RT-PCR and RACE, we identified and cloned the human cDNA homologue, designated CNGB3, which encodes an 809 amino acid polypeptide. Northern blot analysis revealed a major transcript of approximately 4.4 kb specifically expressed in the retina. The human CNGB3 gene consists of 18 exons distributed over approximately 200 kb of genomic sequence. Analysis of the CNGB3 gene in achromats revealed six different mutations including a missense mutation (S435F), two stop codon mutations (R203X and E336X), a 1 bp and an 8 bp deletion (1148delC and 819-826del) and a putative splice site mutation of intron 13. The 1148delC mutation was identified recurrently in several families, and in total was present on 11 of 22 disease chromosomes segregating in our families.

Voltage-induced release of nucleic acids from palaeontological samples.

Most of the protocols for the recovery of ancient DNA from palaeontological specimens are time-consuming and tend to yield inconsistent polymerase chain reaction (PCR) results. "Voltage-induced release" is a novel and rapid approach for the extraction of ancient DNA. Nucleic acids are directly electrophoresed out of powder derived from hard and soft tissues. This technique is much faster than other methods in which pulverized tissue conventionally undergoes time-consuming crude lysis steps. The total preparation time is 5-6 h. The reliability of the voltage-induced release method was validated by (i) measuring the ratio of D-to L-enantiomers of the amino acids aspartic acid, alanine, and leucine, and (ii) by specific PCR amplification of four single-copy markers of human chromosome 17 and 18. We compare voltage-induced release to a frequently used silica-based protocol. DNA extracted employing voltage-induced release was more effective in PCR amplifications, which may be attributed to the effective removal of PCR inhibitors.

Adaptor-mediated amplification of minute amounts of severely fragmented ancient nucleic acids.

It has been repeatedly shown that high copy number mitochondrial DNA sequences can be recovered from ancient samples. A significant increase in the volume of information available to researchers will be observed when the amplification of nuclear DNA becomes commonplace and reproducible. To this end we established a modification of the Rapid Amplification of cDNA Ends (RACE) procedure normally used for the generation of cDNA ends from adaptor-ligated expressed sequence tag libraries. The modifications were designed to specifically address the problems associated with the highly damaged nucleic acids extracted from palaeontological specimens. For this study we used 6 human samples dating to 450 AD and approximately 6.500 BP that were refractory to reliable amplification of single copy loci by PCR. Racemate contents (ratio of D/L enantiomers) of aspartic acid, alanine, and leucine also indicated that no amplifiable DNA is present in 5 of the 6 samples. The proposed technique allowed us (i) to amplify four X-chromosomal loci from 5 human specimens, and (ii) to correct allelic drop-out phenomena at the amelogenin locus in one individual; thus showing that the threshold of 80 x 10-3 for D/Lasp as a borderline for the presence/absence of amplifiable aDNA requires reassessment. Reliability of the proposed technique (i.e. amplification of DNA sequences endogenous to the find) was validated by the application of "ancient RACE" (aRACE) to prehistoric animal samples.

Human rod monochromacy: linkage analysis and mapping of a cone photoreceptor expressed candidate gene on chromosome 2q11.

We have performed linkage analysis in eight families with rod monochromacy, an autosomal recessively inherited condition with complete color blindness. Significant linkage was found with markers located at the pericentromeric region of chromosome 2. A maximum lod score of 5.36 was obtained for marker D2S2333 at theta = 0.00. Mapping of meiotic breakpoints localized the disease gene between markers D2S2187 and D2S2229. Homozygosity for a number of subsequent markers indicating identity by descent was found in two families and provides evidence for a further refinement of the locus proximal to D2S373. This defines an interval of approximately 3 cM covering the ACHM2 locus for rod monochromacy. Radiation hybrid mapping of the CNGA3 gene encoding the alpha-subunit of the cGMP gated cation channel in human cone photoreceptors resulted in a maximum lod score of 16.1 with marker D2S2311 combined with a calculated physical distance of 6.19cR10,000. Screening of the CEPH YAC library and subsequent STS mapping indicated the physical order cen-D2S2222-D2S2175-(D2S2187/D2S2311)-qtel ofmarkers on 2q11 and showed that the CNGA3 gene maps most closely to D2S2187 and D2S2311. These data indicate that the CNGA3 gene maps within the critical interval of the ACHM2 locus for rod monochromacy and thus is a candidate gene for this disease.