Oleg V. Evgrafov

Y-Chromosomal Diversity in Europe Is Clinal and Influenced Primarily by Geography, Rather than by Language

Clinal patterns of autosomal genetic diversity within Europe have been interpreted in previous studies in terms of a Neolithic demic diffusion model for the spread of agriculture; in contrast, studies using mtDNA have traced many founding lineages to the Paleolithic and have not shown strongly clinal variation. We have used 11 human Y-chromosomal biallelic polymorphisms, defining 10 haplogroups, to analyze a sample of 3,616 Y chromosomes belonging to 47 European and circum-European populations. Patterns of geographic differentiation are highly nonrandom, and, when they are assessed using spatial autocorrelation analysis, they show significant clines for five of six haplogroups analyzed. Clines for two haplogroups, representing 45% of the chromosomes, are continentwide and consistent with the demic diffusion hypothesis. Clines for three other haplogroups each have different foci and are more regionally restricted and are likely to reflect distinct population movements, including one from north of the Black Sea. Principal-components analysis suggests that populations are related primarily on the basis of geography, rather than on the basis of linguistic affinity. This is confirmed in Mantel tests, which show a strong and highly significant partial correlation between genetics and geography but a low, nonsignificant partial correlation between genetics and language. Genetic-barrier analysis also indicates the primacy of geography in the shaping of patterns of variation. These patterns retain a strong signal of expansion from the Near East but also suggest that the demographic history of Europe has been complex and influenced by other major population movements, as well as by linguistic and geographic heterogeneities and the effects of drift.

Identification and Analysis of Mutations in the Wilson Disease Gene (ATP7B): Population Frequencies, Genotype-Phenotype Correlation, and Functional Analyses

Wilson disease (WD) is an autosomal recessive disorder characterized by toxic accumulation of copper in the liver and subsequently in the brain and other organs. On the basis of sequence homology to known genes, the WD gene (ATP7B) appears to be a copper-transporting P-type ATPase. A search for ATP7B mutations in WD patients from five population samples, including 109 North American patients, revealed 27 distinct mutations, 18 of which are novel. A composite of published findings shows missense mutations in all exons-except in exons 1-5, which encode the six copper-binding motifs, and in exon 21, which spans the carboxy-terminus and the poly(A) tail. Over one-half of all WD mutations occur only rarely in any population sample. A splice-site mutation in exon 12 accounts for 3% of the WD mutations in our sample and produces an in-frame, 39-bp insertion in mRNA of patients homozygous, but not heterozygous, for the mutation. The most common WD mutation (His1069Glu) was represented in approximately 38% of all the WD chromosomes from the North American, Russian, and Swedish samples. In several population cohorts, this mutation deviated from Hardy-Weinberg equilibrium, with an overrepresentation of homozygotes. We did not find a significant correlation between His1069Glu homozygosity and several clinical indices, including age of onset, clinical manifestation, ceruloplasmin activity, hepatic copper levels, and the presence of Kayser-Fleischer rings. Finally, lymphoblast cell lines from individuals homozygous for His1069Glu and 4 other mutations all demonstrated significantly decreased copper-stimulated ATPase activity.

Screening for mutations in the peripheral myelin genes PMP22, MPZ and Cx32 (GJB1) in Russian Charcot‐Marie‐Tooth neuropathy patients

Charcot‐Marie‐Tooth disease (CMT) and related inherited peripheral neuropathies, including Dejerine‐Sottas syndrome, congenital hypomyelination, and hereditary neuropathy with liability to pressure palsies (HNPP), are caused by mutations in three myelin genes: PMP22, MPZ and Cx32 (GJB1). The most common mutations are the 1.5 Mb CMT1A tandem duplication on chromosome 17p11.2‐p12 in CMT1 patients and the reciprocal 1.5 Mb deletion in HNPP patients. We performed a mutation screening in 174 unrelated CMT patients and three HNPP families of Russian origin. The unrelated CMT patients included 108 clinically and electrophysiologically diagnosed CMT1 cases, 32 CMT2 cases, and 34 cases with unspecified CMT. Fifty‐nine CMT1A duplications were found, of which 58 belonged to the CMT1 patient group. We found twelve distinct mutations in Cx32, six mutations in MPZ, and two mutations in PMP22. Of these respectively, eight, five, and two lead to a CMT1 phenotype. Eight mutations (Cx32: Ile20Asn/Gly21Ser, Met34Lys, Leu90Val, and Phe193Leu; MPZ: Asp134Gly, Lys138Asn, and Thr139Asn; PMP22: ValSer25‐26del) were not reported previously. Phenotype–genotype correlations were based on nerve conduction velocity studies and mutation type. Hum Mutat 15:340–347, 2000.

A new locus for autosomal dominant Charcot-Marie-Tooth disease type 2 (CMT2F) maps to chromosome 7q11-q21

Charcot-Marie-Tooth disease (CMT) constitutes a genetically heterogeneous group of inherited motor and sensory peripheral neuropathies. The axonal type of CMT is designated CMT type 2 (CMT2). Four loci for autosomal dominant CMT2 have been reported so far. Only in CMT2E, linked to chromosome 8p21, disease-causing mutations in the gene for neurofilament light chain (NEFL) were identified. In this study we report a multigenerational Russian family with autosomal dominant CMT2 and assign the locus to chromosome 7q11-q21. The CMT2 neuropathy in this family represents a novel genetic entity designated CMT2F.

657del5 mutation in the gene for Nijmegen breakage syndrome (NBS1) in a cohort of russian children with lymphoid tissue malignancies and controls

Nijmegen breakage syndrome (NBS, OMIM 251260) is a rare hereditary disease, characterized by immune deficiency, microcephaly, and an extremely high incidence of lymphoid tissue malignancies. The gene mutated in NBS, NBS1, was recently cloned from its location on chromosome 8q21. The encoded protein, nibrin (p95), together with hMre11 and hRad50, is involved in the double‐strand DNA break repair system. We screened two Russian cohorts for the 657del5 NBS1 mutation and found no carriers in 548 controls and two carriers in 68 patients with lymphoid malignancies: one with acute lymphoblastic leukemia (ALL) and one with non‐Hodgkin lymphoma (NHL). Several relatives of the second patient, who were carriers of the same mutation, had cancer (ALL, breast cancer, GI cancers). These preliminary data suggest that NBS1 mutation carriers can be predisposed to malignant disorders.

The Use of Y-Chromosomal DNA Variation to Investigate Population History

Y-chromosomal DNA lineages can be used to trace the origins of males in modern populations. A combination of biallelic markers has been used to identify “haplogroup 3” Y chromosomes, which are widespread and common in many European and Asian populations. Microsatellite analysis shows that the diversity of haplogroup 3 chromosomes is low, suggesting a recent spread.

GH-1 gene splicing mutations: molecular basis of hereditary isolated growth hormone deficiency in children.

Children, residents of the Russian Federation, with congenital isolated growth hormone deficiency, were screened for mutations of GH-1 gene, the main gene of this deficiency. Twenty-eight children from 26 families with total congenital isolated growth hormone deficiency were examined. Direct sequencing of GH-1 detected five splicing mutations in intron 2, intron 3, and exon 4, two of them were never described previously. Three dominant negative mutations of GH-1 splicing, the basis for autosomal dominant isolated growth hormone deficiency (type II), are presented: IVS2 −2A>T, IVS3 +2T>C, and IVS3 +1G<A. GH-1 is the main gene of type II isolated growth hormone deficiency in patients living in the Russian Federation. All detected mutations of GH-1 impair splicing processes, which distinguishes them from mutations in other forms of isolated growth hormone deficiency. The detected variety of GH-1 splicing mutations attests to allele genetic heterogeneity of this pathology. The “hot spot” of mutations is 5′-donor splicing site of GH-1 intron 3, while IVS3 +1G>A mutation can be regarded as the most incident in type II isolated growth hormone deficiency in the Russian population.