Michele D'Urso

Folate treatment and unbalanced methylation and changes of allelic expression induced by hyperhomocysteinaemia in patients with uraemia

BACKGROUND Hyperhomocysteinaemia occurs in several genetically determined and acquired disorders and is highly prevalent in patients with uraemia. In these disorders, homocysteine precursor S-adenosylhomocysteine, a powerful competitive inhibitor of S-adenosylmethionine-dependent methyltransferases, is increased, suggesting unbalanced methylation. We aimed to investigate whether DNA hypomethylation is present in patients with uraemia who also have hyperhomocysteinaemia and whether regulation of specific classes of genes, dependent on DNA methylation, is compromised. METHODS We selected men with hyperhomocysteinaemia and uraemia who were having standard haemodialysis treatment, and compared them with healthy male controls. We measured the homocysteine concentration from plasma samples and obtained DNA and RNA samples from peripheral mononuclear cells. DNA methylation was assessed by cytosine extension assay and by Southern blotting. Allelic expression of pseudoautosomal and imprinted genes was investigated by analysis of suitable restriction fragment length polymorphisms. FINDINGS Total DNA hypomethylation was higher in patients than in controls (z score -4.593, p=0.0006) and allelic expression was changed in both sex-linked and imprinted genes. The shift from monoallelic to biallelic expression was dependent on homocysteine concentrations. Folate therapy, a common method to reduce hyperhomocysteinaemia, restored DNA methylation to normal levels and corrected the patterns of gene expression. INTERPRETATION Our results suggest that hyperhomocysteinaemia affects epigenetic control of gene expression, which can be reverted by folate treatment. Our data support the hypothesis that the toxic action of homocysteine can be mediated by macromolecule hypomethylation.

Transcriptome analysis of mouse stem cells and early embryos.

Understanding and harnessing cellular potency are fundamental in biology and are also critical to the future therapeutic use of stem cells. Transcriptome analysis of these pluripotent cells is a first step towards such goals. Starting with sources that include oocytes, blastocysts, and embryonic and adult stem cells, we obtained 249,200 high-quality EST sequences and clustered them with public sequences to produce an index of approximately 30,000 total mouse genes that includes 977 previously unidentified genes. Analysis of gene expression levels by EST frequency identifies genes that characterize preimplantation embryos, embryonic stem cells, and adult stem cells, thus providing potential markers as well as clues to the functional features of these cells. Principal component analysis identified a set of 88 genes whose average expression levels decrease from oocytes to blastocysts, stem cells, postimplantation embryos, and finally to newborn tissues. This can be a first step towards a possible definition of a molecular scale of cellular potency. The sequences and cDNA clones recovered in this work provide a comprehensive resource for genes functioning in early mouse embryos and stem cells. The nonrestricted community access to the resource can accelerate a wide range of research, particularly in reproductive and regenerative medicine.

Structural analysis of the X-linked gene encoding human glucose 6-phosphate dehydrogenase.

We report the isolation and analysis of human genomic DNA clones spanning about 100 kb of the X chromosome and comprising the entire gene coding for the enzyme glucose 6‐phosphate dehydrogenase (G6PD). The G6PD gene is 18 kb long and consists of 13 exons: the protein‐coding region is divided into 12 segments ranging in size from 12 to 236 bp; an intron is present in the 5′ untranslated region. Mature G6PD mRNA has a single polyadenylation site in HeLa cells. The major 5′ end of mature G6PD mRNA in several cell lines is located 177 bp upstream of the translation initiating codon; longer mRNA molecules extending further in the 5′ direction could be identified by S1 mapping and by comparing genomic and cDNA sequences. The DNA sequence around the major mRNA start is very GC rich; as to putative transcription regulatory sequences, a non‐canonical TATA box and 9 CCGCCC elements are present, but no CAAT element could be identified. The genomic DNA we have isolated includes another ubiquitously transcribed region, provisionally named the GdX gene. Although the function of GdX is as yet unknown, we have established that this gene is located about 40 kb downstream of G6PD and is transcribed in the same direction. A comparative analysis of the promoter region of G6PD and 10 other housekeeping enzyme genes has confirmed the presence of a number of common features. In particular, in the eight cases in which a ‘TATA’ box is present, a conserved sequence of 25 bp is seen immediately downstream.

Functional analysis of MLH1 mutations linked to hereditary nonpolyposis colon cancer

Hereditary nonpolyposis colon cancer (HNPCC) is associated with malfunction of postreplicative mismatch repair (MMR). While a majority of HNPCC‐associated mutations in the MMR genes MLH1, MSH2, or MSH6 genes cause truncations—and thus loss of function—of the respective polypeptides, little is currently known about the biochemical defects associated with nontruncating mutations. We studied the interactions of six MLH1 variants, carrying either missense mutations or in‐frame deletions, with normal PMS2 and tested the functionality of these heterodimers of MLH1 and PMS2 (MutLα) in an in vitro MMR assay. Three MLH1 carboxy‐terminal mutations, consisting of internal deletions of exon 16 (amino acids 578–632) or exon 17 (amino acids 633–663), or a missense R659P mutation in exon 17, affected the formation of a functional MutLα. Interestingly, mutations C77R and I107R in the amino‐terminal part of MLH1 did not affect its heterodimerization with PMS2. The complexes MLH1(C77R)/PMS2 and MLH1(I107R)/PMS2, however, failed to complement a MMR‐deficient extract lacking a functional MutLα. As all these five mutations were identified in typical HNPCC families and produce nonfunctional proteins, they can be considered disease‐causing. In contrast, the third amino‐terminal mutation S93G did not affect the heterodimerization, and the MLH1(S93G)/PMS2 variant was functional in the in vitro MMR assay, given thus the nature of the HNPCC family in question. Although the missense mutation segregates with the disease, the mean age of onset in the family is unusually high (∼65 years).

Longins: a new evolutionary conserved VAMP family sharing a novel SNARE domain

This article describes the discovery of a novel SNARE domain that might be involved in the regulation of membrane fusion. This domain is shared by a novel family of VAMPs called long VAMPs or longins. Members of this family are more conserved among eukaryotes than are classical VAMPs, possibly because of their underlying basic SNARE function.

Sequence of human glucose-6-phosphate dehydrogenase cloned in plasmids and a yeast artificial chromosome

The sequence of 20,114 bp of DNA including the human glucose-6-phosphate dehydrogenase (G6PD) gene was determined. The region included a prominent CpG island, starting about 680 nucleotides upstream of the transcription start site, extending about 1050 nucleotides downstream of the start site, and ending just at the start of the first intron. The transcribed region from the start site to the poly(A) addition site covers 15,860 bp. The sequence of the 13 exons agreed with published cDNA sequence and for the 11 exons tested, with the corresponding sequence in a yeast artificial chromosome (YAC). The latter confirms YAC cloning fidelity at the DNA sequence level. Sixteen Alu sequences constitute 24% of the total sequence tract. Four were outside the borders of the mRNA transcript of the gene; all the others were found in a large (9858 bp) intron between exons 2 and 3. Two Alu clusters each contain Alus lying between the monomers of another.

Mapping human chromosomes by walking with sequence-tagged sites from end fragments of yeast artificial chromosome inserts.

Sequence-tagged sites (STSs) derived from end fragments of chromosome-specific yeast artificial chromosomes (YACs) can facilitate the assembly of an overlapping YAC/STS map. Contigs form rapidly by iteratively screening YAC collections with end-fragment STSs from YACs that have not yet been detected by any previous STS. The map is rendered rapidly useful during its assembly by incorporating supplementary STSs from genes and genetic linkage probes with known locations. Methods for the systematic development and testing of the end-fragments STSs are given here, and a group of 100 STSs is presented for the X chromosome. The mapping strategy is shown to be successful in simulations with portions of the X chromosome already largely mapped into overlapping YACs by other means.

Alterations of the IKBKG Locus and Diseases: An Update and a Report of 13 Novel Mutations

Mutations in the inhibitor of kappa light polypeptide gene enhancer in B‐cells, kinase gamma (IKBKG), also called nuclear factor‐kappaB (NF‐kB) essential modulator (NEMO), gene are the most common single cause of incontinentia pigmenti (IP) in females and anhydrotic ectodermal dysplasia with immunodeficiency (EDA‐ID) in males. The IKBKG gene, located in the Xq28 chromosomal region, encodes for the regulatory subunit of the inhibitor of kappaB (IkB) kinase (IKK) complex required for the activation of the NF‐kB pathway. Therefore, the remarkably heterogeneous and often severe clinical presentation reported in IP is due to the pleiotropic role of this signaling transcription pathway. A recurrent exon 4_10 genomic rearrangement in the IKBKG gene accounts for 60 to 80% of IP‐causing mutations. Besides the IKBKG rearrangement found in IP females (which is lethal in males), a total of 69 different small mutations (missense, frameshift, nonsense, and splice‐site mutations) have been reported, including 13 novel ones in this work. The updated distribution of all the IP‐ and EDA‐ID‐causing mutations along the IKBKG gene highlights a secondary hotspot mutation in exon 10, which contains only 11% of the protein. Furthermore, familial inheritance analysis revealed an unexpectedly high incidence of sporadic cases (>65%). The sum of the observations can aid both in determining the molecular basis of IP and EDA‐ID allelic diseases, and in genetic counseling in affected families. Hum Mutat 29(5), 595–604, 2008.

Mutation analysis of the MECP2 gene in British and Italian Rett syndrome females

Abstract. Rett syndrome is an X-linked dominant neurological disorder, which appears to be the commonest genetic cause of profound combined intellectual and physical disability in Caucasian females. Recently, this syndrome has been associated with mutations of the MECP2 gene, a transcriptional repressor of still unknown target genes. Here we report a detailed mutational analysis of 62 patients from UK and Italian archives, representing the first comparative study among different populations and one of the largest number of cases so far analyzed. We review the literature on MECP2 mutations in Rett syndrome. This analysis has permitted us to produce a map of the recurrent mutations identified in this and previous studies. Bioinformatic analysis of the mutations, taking advantage of structural and evolutionary data, leads us to postulate the existence of a new functional domain in the MeCP2 protein, which is conserved among brain-specific regulatory factors.

Yeast artificial chromosome-based genome mapping: Some lessons from Xq24–q28

Yeast artificial chromosomes (YACs) have recently provided a potential route to long-range coverage of complex genomes in contiguous cloned DNA. In a pilot project for 50 Mb (1.5% of the human genome), a variety of techniques have been applied to assemble Xq24-q28 YAC contigs up to 8 Mb in length and assess their quality. The results indicate the relative strength of several approaches and support the adequacy of YAC-based methods for mapping the human genome.