Physical and genetic characterization reveals a pseudogene, an evolutionary junction, and unstable loci in distal Xq28

Principles of genetic variations and molecular diseases: applications in hemophilia A

DNA structure alterations are the ultimate source of genetic variations. Without them, evolution would be impossible. While they are essential for DNA diversity, defects in DNA synthesis can lead to numerous genetic diseases. Due to increasingly innovative technologies, our knowledge of the human genome and genetic diseases has grown considerably over the last few years, allowing us to detect another class of variants affecting the chromosomal structure. DNA sequence can be altered in multiple ways: DNA sequence changes by substitution, deletion, or duplication of some nucleotides; chromosomal structure alterations by deletion, duplication, translocation, and inversion, ranging in size from kilobases to mega bases; changes in the cell's genome size. If the alteration is located within a gene and sufficiently deleterious, it can cause genetic disorders. Due to the F8 gene's high rate of new small mutations and its location at the tip of X chromosome, containing high repetitive sequences, a wide variety of genetic variants has been described as the cause of hemophilia A (HA). In addition to the F8 intron 22 repeat inversion, HA can also result from point mutations, other inversions, complex rearrangements, such as duplications or deletions, and transposon insertions causing phenotypes of variable severity characterized by complete or partial deficiency of circulating FVIII. This review aims to present the origins, mechanisms, and consequences of F8 alterations. A sound understanding of the multiple genetic mechanisms responsible for HA is essential to determine the appropriate strategy for molecular diagnosis and detected each type of genetic variant.

MECP2 Duplication Syndrome

Since the initial report that clearly established a causal role between duplication of the MECP2 gene and a severe syndromic form of intellectual disability, many new patients have been identified and reported, and the etiology in already published families solved. This has led to the establishment of a clinically recognizable disorder. Here, we review the clinical data of 129 reported and nonreported male patients with MECP2 duplication syndrome.

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.

Nonrecurrent MECP2 duplications mediated by genomic architecture-driven DNA breaks and break-induced replication repair

Recurrent submicroscopic genomic copy number changes are the result of nonallelic homologous recombination (NAHR). Nonrecurrent aberrations, however, can result from different nonexclusive recombination-repair mechanisms. We previously described small microduplications at Xq28 containing MECP2 in four male patients with a severe neurological phenotype. Here, we report on the fine-mapping and breakpoint analysis of 16 unique microduplications. The size of the overlapping copy number changes varies between 0.3 and 2.3 Mb, and FISH analysis on three patients demonstrated a tandem orientation. Although eight of the 32 breakpoint regions coincide with low-copy repeats, none of the duplications are the result of NAHR. Bioinformatics analysis of the breakpoint regions demonstrated a 2.5-fold higher frequency of Alu interspersed repeats as compared with control regions, as well as a very high GC content (53%). Unexpectedly, we obtained the junction in only one patient by long-range PCR, which revealed nonhomologous end joining as the mechanism. Breakpoint analysis in two other patients by inverse PCR and subsequent array comparative genomic hybridization analysis demonstrated the presence of a second duplicated region more telomeric at Xq28, of which one copy was inserted in between the duplicated MECP2 regions. These data suggest a two-step mechanism in which part of Xq28 is first inserted near the MECP2 locus, followed by breakage-induced replication with strand invasion of the normal sister chromatid. Our results indicate that the mechanism by which copy number changes occur in regions with a complex genomic architecture can yield complex rearrangements.

Functional characterization of the TMLH gene: promoter analysis, in situ hybridization, identification and mapping of alternative splicing variants

Carnitine is a molecule with well-documented pleiotropic functions whose biosynthesis involves four catalytic steps. Here, we report a detailed analysis of the expression and transcriptional control of TMLH gene, which codifies for the first enzyme of carnitine biosynthesis. TMLH maps at the extreme end of Xq28, a chromosomal region of high genomic instability. By 5' and 3' RACE, we identified and mapped two alternative 5' TMLH first exons and seven alternative 3'-splice variants, which are spread over a genomic region of about 250 kb. While the two alternative 5' exons have different expression profiles, all the 3' alternative forms are ubiquitously expressed. Reporter assays revealed that the 3'-UTRs of each TMLH isoform might influence its own expression at post-transcriptional level. In addition, we identified a highly conserved promoter region of TMLH. Functional analysis of this region showed the presence of a CpG island, whose methylation-status could control the level of TMLH transcription. Finally, by mRNA in situ hybridization, we found that TMLH expression is present at E12.5 dpc in the mouse liver, lung and brain, and is then maintained in the postnatal brain with a specific neuronal pattern. Collectively, our data highlight a tight transcriptional and post-transcriptional control of TMLH expression.

NEMO, NFkappaB signaling and incontinentia pigmenti

The identification of mutations in the NEMO gene in humans with incontinentia pigmenti and several other genetic conditions has led to an appreciation of the multiple roles of signaling through the NFkappaB pathway, and how erroneous signalling contributes to disease. The finding that the disease results from a common, recurrent mutation was surprising given the high variability in patients' phenotypes and illustrates the role of X inactivation and selection in females. Recent advances in mouse models and in understanding the multiple roles of NEMO in the cell provide additional avenues to define the various roles of NEMO in NFkappaB signaling.

Gene conversion and evolution of Xq28 duplicons involved in recurring inversions causing severe hemophilia A

Inversions breaking the 1041 bp int1h-1 or the 9.5-kb int22h-1 sequence of the F8 gene cause hemophilia A in 1/30,000 males. These inversions are due to homologous recombination between the above sequences and their inverted copies on the same DNA molecule, respectively, int1h-2 and int22h-2 or int22h-3. We find that (1) int1h and int22h duplicated more than 25 million years ago; (2) the identity of the copies (>99%) of these sequences in humans and other primates is due to gene conversion; (3) gene conversion is most frequent in the internal regions of int22h; (4) breakpoints of int22h-related inversions also tend to involve the internal regions of int22h; (5) sequence variations in a sample of human X chromosomes defined eight haplotypes of int22h-1 and 27 of int22h-2 plus int22h-3; (6) the latter two sequences, which lie, respectively, 500 and 600 kb telomeric to int22h-1 are five-fold more identical when in cis than when in trans, thus suggesting that gene conversion may be predominantly intrachromosomal; (7) int1h, int22h, and flanking sequences evolved at a rate of about 0.1% substitutions per million years during the divergence between humans and other primates, except for int1h during the human-chimpanzee divergence, when its rate of evolution was significantly lower. This is reminiscent of the slower evolution of palindrome arms in the male specific regions of the Y chromosome and we propose, as an explanation, that intrachromosomal gene conversion and cosegregation of the duplicated regions favors retention of the ancestral sequence and thus reduces the evolution rate.

Identification of a 650 kb duplication at the X chromosome breakpoint in a patient with 46,X,t(X;8)(q28;q12) and non-syndromic mental retardation

A female patient with non-syndromic mental retardation was shown by high resolution GTL banding to have inherited an apparently balanced translocation, 46,X,t(X;8)(q28;q12)mat. Replication studies in the mother and daughter showed a skewed X inactivation pattern in lymphocytes, with the normal X chromosome preferentially inactivated. The mother also had significant intellectual disability. To investigate the possibility that a novel candidate gene for XLMR was disrupted at the X chromosome translocation breakpoint, we mapped the breakpoint using fluorescence in situ hybridisation (FISH). This showed that the four known genes involved in non-syndromic mental retardation in Xq28, FMR2, SLC6A8, MECP2, and GDI1, were not involved in the translocation. Intriguingly, we found that the X chromosome breakpoint in the daughter could not be defined by a single breakpoint spanning genomic clone and further analysis showed a 650 kb submicroscopic duplication between DXS7067 and DXS7060 on either side of the X chromosome translocation breakpoint. This duplicated region contains 11 characterised genes, of which nine are expressed in brain. Duplication of one or several of the genes within the 650 kb interval is likely to be responsible for the mental retardation phenotype seen in our patient. Xq28 appears to be an unstable region of the human genome and genomic rearrangements are recognised as major causes of two single gene defects, haemophilia A and incontinentia pigmenti, which map within Xq28. This patient therefore provides further evidence for the instability of this genomic region.