Identification of Intron Retention in the Slc16a3 Gene Transcript Encoding the Transporter MCT4 in the Brain of Aged and Alzheimer-Disease Model (APPswePS1dE9) Mice.

The monocarboxylate transporter 4 (MCT4; Slc16a3) is expressed in the central nervous system, notably by astrocytes. It is implicated in lactate release and the regulation of glycolytic flux. Whether its expression varies during normal and/or pathological aging is unclear. As the presence of its mature transcript in the brain of young and old mice was determined, an unexpectedly longer RT-PCR fragment was detected in the mouse frontal cortex and hippocampus at 12 vs. 3 months of age. Cultured astrocytes expressed the expected 516 base pair (bp) fragment but treatment with IL-1ß to mimic inflammation as can occur during aging led to the additional expression of a 928 bp fragment like that seen in aged mice. In contrast, cultured pericytes (a component of the blood-brain barrier) only exhibited the 516 bp fragment. Intriguingly, cultured endothelial cells constitutively expressed both fragments. When RT-PCR was performed on brain subregions of an Alzheimer mouse model (APPswePS1dE9), no fragment was detected at 3 months, while only the 928 bp fragment was present at 12 months. Sequencing of MCT4 RT-PCR products revealed the presence of a remaining intron between exon 2 and 3, giving rise to the longer fragment detected by RT-PCR. These results unravel the existence of intron retention for the MCT4 gene in the central nervous system. Such alternative splicing appears to increase with age in the brain and might be prominent in neurodegenerative diseases such as Alzheimer's disease. Hence, further studies in vitro and in vivo of intron 2 retention in the Slc16a3 gene transcript are required for adequate characterization concerning the biological roles of Slc16a3 isoforms in the context of aging and Alzheimer's disease pathology.

Three Complex alleles associated with N1303K mutation and their molecular consequences.

Cystic Fibrosis (CF) in Arab Mediterranean countries has a different CFTR mutational profile if compared either to Caucasians or in the Arabian Peninsula. The c.3909C>G (N1303K, p.Asn1303Lys) mutation of the Cystic Fibrosis Transmembrane Conductance Regulator gene (CFTR). This mutation represents a higher frequency in the Mediterranean countries in association with different polymorphisms or mutations in cis position constituting various complex alleles. N1303K mutation induces many phenotypes, especially pancreatic insufficiency from mild to severe and it is associated in cis with other polymorphisms. The aim of this investigation is therefore to screen complex alleles carrying N1303K mutation among Lebanese, Egyptian and French patients. All exons of the CFTR and their flanking regions were performed by PCR amplification, followed by automated direct DNA sequencing. Two complex alleles are more frequent corresponding to Wild Type and mutated haplotype. Besides that two other very rare complex alleles have been detected, one in Egyptian and French samples, and then another one in Lebanon samples. We have studied their impact on the CFTR mRNA splicing using a minigene strategy. Constructs containing wild-type and mutant CFTR cloned into the pTBNdeI hybride minigene have been expressed in HeLa, HT29 and HEK293 cells. RT-PCR analysis of mRNA using ß-globin-specific primers revealed that N1303K and the polymorphisms associated with cis induce weak abnormal splicing and a modification of the quality and the quantity of CFTR protein. These different associations of identified polymorphisms with N1303K in cis could have an impact on the severity of the disease.

Complexity of phenotypes induced by p.Asn1303Lys-CFTR correlates with difficulty to rescue and activate this protein.

Cystic Fibrosis is the most common recessive autosomal rare disease found in Caucasian. It is caused by mutations on the Cystic Fibrosis Transmembrane Conductance Regulator gene (CFTR) that encodes for a protein located on the apical membrane of epithelial cells. c.3909C>G (p.Asn1303Lys) is one of the most common worldwide mutations located in nucleotide binding domain 2. The effect of the p.Asn1303Lys mutation on misprocessing was studied by immunofluorescence and western blotting analysis in presence and absence of treatment. To evaluate the functionality of potentially rescued p.Asn1303Lys-CFTR, we assessed the channel activity by radioactive iodide efflux. No recovery of the activity was observed in transfected cultured cells treated with VX-809. Thus, our results suggest that multiple drugs may be needed for the treatment of c.3909C>G patients in order to correct and activate p.Asn1303Lys-CFTR as it shows folding and functional defects.

In cellulo analyses of the p.Val322Ala mutation on the CFTR protein conformation and activity.

Cystic fibrosis is caused by mutations on the Cystic Fibrosis Transmembrane conductance Regulator gene (CFTR). Exonic mutations may have variable effect on the CFTR protein and may alter the normal localization of CFTR on the apical membrane of epithelial cells or/and its function as a chloride channel. Identifying the effect of a missense mutation can be a first step in helping the medical counseling and the therapeutic strategies. In this study, the effect of the c.965T>C exon 8 mutation that induces a valine-to-alanine substitution (p.Val322Ala) into the fifth helix of the first membrane spanning domain was determined by in silico and in cellulo analyses. The confocal microscopy analyses and functionality test showed, in the tested cell line, that this mutation should have no impact on the function of the p.Val322Ala-CFTR protein. However, regarding the importance of this Val322 amino acid in the CFTR protein, precautions and individual follow-up are still required when c.965T>C if associated with other mutation(s).

N1303K (c.3909C>G) mutation and splicing: implication of its c.[744-33GATT(6); 869+11C>T] complex allele in CFTR exon 7 aberrant splicing.

Cystic Fibrosis is the most common recessive autosomal rare disease found in Caucasians. It is caused by mutations on the Cystic Fibrosis Transmembrane Conductance Regulator gene (CFTR) that encodes a protein located on the apical membrane of epithelial cells. c.3909C>G (p.Asn1303Lys, old nomenclature: N1303K) is one of the most common worldwide mutations. This mutation has been found at high frequencies in the Mediterranean countries with the highest frequency in the Lebanese population. Therefore, on the genetic level, we conducted a complete CFTR gene screening on c.3909C>G Lebanese patients. The complex allele c.[744-33GATT(6); 869+11C>T] was always associated with the c.3909C>G mutation in cis in the Lebanese population. In cellulo splicing studies, realized by hybrid minigene constructs, revealed no impact of the c.3909C>G mutation on the splicing process, whereas the associated complex allele induces minor exon skipping.

Multi-physiopathological consequences of the c.1392G>T CFTR mutation revealed by clinical and cellular investigations.

This study combines a clinical approach and multiple level cellular analyses to determine the physiopathological consequences of the c.1392G>T (p.Lys464Asn) CFTR exon 10 mutation, detected in a CF patient with a frameshift deletion in trans and a TG(11)T(5) in cis. Minigene experiment, with different TG(m)T(n) alleles, and nasal cell mRNA extracts were used to study the impact of c.1392G>T on splicing in both in cellulo and in vivo studies. The processing and localization of p.Lys464Asn protein were evaluated, in cellulo, by western blotting analyses and confocal microscopy. Clinical and channel exploration tests were performed on the patient to determine the exact CF phenotype profile and the CFTR chloride transport activity. c.1392G>T affects exon 10 splicing by inducing its complete deletion and encoding a frameshift transcript. The polymorphism TG(11)T(5) aggravates the effects of this mutation on aberrant splicing. Analysis of mRNA obtained from parental airway epithelial cells confirmed these in cellulo results. At the protein level the p.Lys464Asn protein showed neither maturated form nor membrane localization. Furthermore, the in vivo channel tests confirmed the absence of CFTR activity. Thus, the c.1392G>T mutation alone or in association with the TG repeats and the poly T tract revealed obvious impacts on splicing and CFTR protein processing and functionality. The c.[T(5); 1392G>T] complex allele contributes to the CF phenotype by affecting splicing and inducing a severe misprocessing defect. These results demonstrate that the classical CFTR mutations classification is not sufficient: in vivo and in cellulo studies of a possible complex allele in a patient are required to provide correct CFTR mutation classification, adequate medical counseling, and adapted therapeutic strategies.

Consequences of partial duplications of the human CFTR gene on cf diagnosis: mutations or ectopic variations.

CFTR exon 10 and its flanking regions are duplicated in the human genome. These duplications present mutations compared to the normal exon 10 sequence. Due to the polymorphic sequence of the 3' intron 9 sequence, it may appear difficult to sequence exon 10 and some mutations described in this exon could, in fact, be variations observed in an ectopic duplicated sequence. In our previous work we described a methodology to carry out PCR only of exon 10 and not of ectopic regions. In this work, we analyzed mutations described in the CF data base as being CFTR mutations but also found in ectopic regions: c.1392G>T, c.1338_1339delAT, c.1235delC, and c.1247A>G. We have shown that these mutations appear to be authentic mutations in CFTR exon 10 and not ectopic variations in analyzed patients. These mutations validate the usefulness of our new strategy in the mutation analysis of this region of CFTR.

General survey of hAT transposon superfamily with highlight on hobo element in Drosophila.

The hAT transposons, very abundant in all kingdoms, have a common evolutionary origin probably predating the plant-fungi-animal divergence. In this paper we present their general characteristics. Members of this superfamily belong to Class II transposable elements. hAT elements share transposase, short terminal inverted repeats and eight base-pairs duplication of genomic target. We focus on hAT elements in Drosophila, especially hobo. Its distribution, dynamics and impact on genome restructuring in laboratory strains as well as in natural populations are reported. Finally, the evolutionary history of hAT elements, their domestication and use as transgenic tools are discussed.

CFTR mutation combinations producing frequent complex alleles with different clinical and functional outcomes.

Genotype-phenotype correlations in cystic fibrosis (CF) may be difficult to establish because of phenotype variability, which is associated with certain CF transmembrane conductance regulator (CFTR) gene mutations and the existence of complex alleles. To elucidate the clinical significance of complex alleles involving p.Gly149Arg, p.Asp443Tyr, p.Gly576Ala, and p.Arg668Cys, we performed a collaborative genotype-phenotype correlation study, collected epidemiological data, and investigated structure-function relationships for single and natural complex mutants, p.[Gly576Ala;Arg668Cys], p.[Gly149Arg;Gly576Ala;Arg668Cys], and p.[Asp443Tyr;Gly576Ala;Arg668Cys]. Among 153 patients carrying at least one of these mutations, only three had classical CF and all carried p.Gly149Arg in the triple mutant. Sixty-four had isolated infertility and seven were healthy individuals with a severe mutation in trans, but none had p.Gly149Arg. Functional studies performed on all single and natural complex mutants showed that (1) p.Gly149Arg results in a severe misprocessing defect; (2) p.Asp443Tyr moderately alters CFTR maturation; and (3) p.Gly576Ala, a known splicing mutant, and p.Arg668Cys mildly alter CFTR chloride conductance. Overall, the results consistently show the contribution of p.Gly149Arg to the CF phenotype, and suggest that p.[Arg668Cys], p.[Gly576Ala;Arg668Cys], and p.[Asp443Tyr;Gly576Ala;Arg668Cys] are associated with CFTR-related disorders. The present study emphasizes the importance of comprehensive genotype-phenotype and functional studies in elucidating the impact of mutations on clinical phenotype.

Influence of the duplication of CFTR exon 9 and its flanking sequences on diagnosis of cystic fibrosis mutations.

The DNA sequences of seven regions in the human genome were examined for sequence identity with exon 9 of the cystic fibrosis transmembrane conductance regulator (CFTR) gene, which is mutated in cystic fibrosis, and its intronic boundaries. These sequences were 95% to 96% homologous. Based on this nucleotide sequence similarity, PCR primers for CFTR exon 9 can potentially anneal with other homologous sequences in the human genome. Sequence alignment analysis of the CFTR exon 9 homologous sequences revealed that five registered mutations in the Cystic Fibrosis Mutation Database may be due to the undesired annealing of primers to a homologous sequence, resulting in inappropriate PCR amplification. For this reason, we propose that certain pseudomutations may result from the similarity between CFTR exon 9 (and its flanking introns) and related sequences in the human genome. Here we show that two mutations previously described in the CFTR database (c.1392 + 6insC; c.1392 + 12G>A) were inappropriately attributed to two individuals who sought carrier testing. A more detailed study by either direct sequencing or subcloning and sequencing of PCR products using specially designed primers revealed that these apparent mutations were not, in fact, present in CFTR. In addition, we present new PCR conditions that permit specific amplification of CFTR exon 9 and its flanking regions.

Residues in the alternative reading frame tumor suppressor that influence its stability and p53-independent activities.

The Alternative Reading Frame (ARF) protein suppresses tumorigenesis through p53-dependent and p53-independent pathways. Most of ARF's anti-proliferative activity is conferred by sequences in its first exon. Previous work showed specific amino acid changes occurred in that region during primate evolution, so we programmed those changes into human p14ARF to assay their functional impact. Two human p14ARF residues (Ala(14) and Thr(31)) were found to destabilize the protein while two others (Val(24) and Ala(41)) promoted more efficient p53 stabilization and activation. Despite those effects, all modified p14ARF forms displayed robust p53-dependent anti-proliferative activity demonstrating there are no significant biological differences in p53-mediated growth suppression associated with simian versus human p14ARF residues. In contrast, p53-independent p14ARF function was considerably altered by several residue changes. Val(24) was required for p53-independent growth suppression whereas multiple residues (Val(24), Thr(31), Ala(41) and His(60)) enabled p14ARF to block or reverse the inherent chromosomal instability of p53-null MEFs. Together, these data pinpoint specific residues outside of established p14ARF functional domains that influence its expression and signaling activities. Most intriguingly, this work reveals a novel and direct role for p14ARF in the p53-independent maintenance of genomic stability.

A novel nuclear interactor of ARF and MDM2 (NIAM) that maintains chromosomal stability.

The ARF tumor suppressor signals through p53 and other poorly defined anti-proliferative pathways to block carcinogenesis. In a search for new regulators of ARF signaling, we discovered a novel nuclear protein that we named NIAM (nuclear interactor of ARF and MDM2) for its ability to bind both ARF and the p53 antagonist MDM2. NIAM protein is normally expressed at low to undetectable levels in cells because of, at least in part, MDM2-mediated ubiquitination and proteasomal degradation. When reintroduced into cells, NIAM activated p53, caused a G1 phase cell cycle arrest, and collaborated with ARF in an additive fashion to suppress proliferation. Notably, NIAM retains growth inhibitory activity in cells lacking ARF and/or p53, and knockdown experiments revealed that it is not essential for ARF-mediated growth inhibition. Thus, NIAM and ARF act in separate anti-proliferative pathways that intersect mechanistically and suppress growth more effectively when jointly activated. Intriguingly, silencing of NIAM accelerated chromosomal instability, and microarray analyses showed reduced NIAM mRNA expression in numerous primary human tumors. This study identifies a novel protein with tumor suppressor-like behaviors and functional links to ARF-MDM2-p53 signaling.

Developmental progression of immunoglobulin heavy chain diversity in sheep.

In order to assess the respective impacts of combinatorial rearrangement, junctional diversification, somatic hypermutation and gene conversion in the generation of immunoglobulin heavy chain variable regions diversity, the sequences of 42 variable regions from late fetal, newborn and young sheep were determined and compared to those of adult animals. At earlier stages of development, the use of germline diversity segments appears restricted, junctional variability is already established, and somatic hypermutations are scarce. The sequence diversity in adults is much higher, which we suggest results from a higher hymermutation activity and possibly from the use of a variety of diversity segments. Altogether, this pattern is very reminiscent of the situation observed in cattle, except for the length of the third complementarity determining regions (CDR3) which are shorter in sheep than in bovine. Unlike the chicken and rabbit systems, it seems that new rearrangements continue to occur in sheep for at least several months after birth.

The ink4a/arf locus evolution in primates: characterization of three ARF sequences.

The human ink4a/arf locus encodes two cell cycle regulatory proteins - the cyclin-dependent kinase inhibitor (p16(ink4a)), and the p53 activator (ARF) - through the use of alternative first exons. This genomic organization is unique in eukaryotes, with two different proteins obtained using different reading frames. The divergence between mouse or opossum and human ARF is very high, whereas proteins have the same nucleolar localization and function. To gain further insights into the relative importance of ARF in different settings, we characterized here the exon 1beta of ARF in 12 different species of primates. We did not find any polymorphism in studied species (monkeys, apes, and humans). These sequences are very similar, with few amino acids substitutions compared to the human sequence. It is strange to find such a high degree of conservation among primates when there is such a low degree of conservation between the human pig, rat, or mouse, chicken exon 1beta sequences. More surprisingly, we observe a threonine at position 31 in all human sequences, whereas an alanine is always present in other sequences. We suggest that when the radiation human/simian appeared or after, a selection of threonine occurred. Moreover, the modifications detected could play a role in different interactions between ARF and other proteins to stabilize or not these complexes.