An evolutionary history of the selectin gene cluster in humans.

Molecules involved in leukocyte trafficking have a central role in the development of inflammatory and immune responses. We performed F(ST) analysis of the selectin cluster, as well as of SELPLG, ICAM1 and VCAM1. Peaks of significantly high population genetic differentiation were restricted to two regions in SELP and one in SELPLG. Resequencing data indicated that the region covering SELP exons 11-13 displays high nucleotide diversity in Africans and Europeans (CEU), and a high level of within-species diversity compared with inter-specific divergence. Analysis of inferred haplotypes revealed a complex phylogeny with two deeply separated clades that coalesce at ~3.5 million years (MY) plus a minor clade with a TMRCA (time to the most recent common ancestor) of ~2.2 MY. A splicing assay indicated no haplotype-specific effect on SELP exon 14 inclusion. These data are consistent with a model of multiallelic balancing selection; single-nucleotide polymorphism analysis indicated that the Val640Leu variant represents a likely selection target. In populations of Asian ancestry a distinct haplotype, possibly carrying regulatory variants, has been driven to high frequency by positive selection. No deviation from neutrality was observed for the SELPLG region. Resequencing of SELP in chimpanzees revealed a haplotype phylogeny with extremely deep basal branches, suggesting either long-standing balancing selection or ancestral population structure. Thus, SELP has experienced a complex selective history, possibly as a result of local adaptation. Variants in the gene have been associated with autoimmune and cardiovascular diseases. Association studies would benefit from both taking the complex SELP haplotype structure into account and from analysis of possible regulatory variants in the gene.

A trans-specific polymorphism in ZC3HAV1 is maintained by long-standing balancing selection and may confer susceptibility to multiple sclerosis.

The human ZC3HAV1 gene encodes an antiviral protein. The longest splicing isoform of ZC3HAV1 contains a C-terminal PARP-like domain, which has evolved under positive selection in primates. We analyzed the evolutionary history of this same domain in humans and in Pan troglodytes. We identified two variants that segregate in both humans and chimpanzees; one of them (rs3735007) does not occur at a hypermutable site and accounts for a nonsynonymous substitution (Thr851Ile). The probability that the two trans-specific polymorphisms have occurred independently in the two lineages was estimated to be low (P = 0.0054), suggesting that at least one of them has arisen before speciation and has been maintained by selection. Population genetic analyses in humans indicated that the region surrounding the shared variants displays strong evidences of long-standing balancing selection. Selection signatures were also observed in a chimpanzee population sample. Inspection of 1000 Genomes data confirmed these findings but indicated that search for selection signatures using low-coverage whole-genome data may need masking of repetitive sequences. A case-control study of more than 1,000 individuals from mainland Italy indicated that the Thr851Ile SNP is significantly associated with susceptibility to multiple sclerosis (MS) (odds ratio [OR] = 1.47, 95% confidence intervals [CI]: 1.08-1.99, P = 0.011). This finding was confirmed in a larger sample of 4,416 Sardinians cases/controls (OR = 1.18, 95% CI: 1.037-1.344, P = 0.011), but not in a population from Belgium. We provide one of the first instances of human/chimpanzee trans-specific coding variant located outside the major histocompatibility complex region. The selective pressure is likely to be virus driven; in modern populations, this variant associates with susceptibility to MS, possibly via the interaction with environmental factors.

Long-term balancing selection maintains trans-specific polymorphisms in the human TRIM5 gene.

The human TRIM5 genes encodes a retroviral restriction factor (TRIM5α). Evolutionary analyses of this gene in mammals have revealed a complex and multifaceted scenario, suggesting that TRIM5 has been the target of exceptionally strong selective pressures, possibly exerted by recurrent waves of retroviral infections. TRIM5 displays inter-individual expression variability in humans and high levels of TRIM5 mRNA have been associated with a reduced risk of HIV-1 infection. We resequenced TRIM5 in chimpanzees and identified two polymorphisms in intron 1 that are shared with humans. Analysis of the gene region encompassing the two trans-specific variants in human populations identified exceptional nucleotide diversity levels and an excess of polymorphism compared to fixed divergence. Most tests rejected the null hypothesis of neutral evolution for this region and haplotype analysis revealed the presence of two deeply separated clades. Calculation of the time to the most recent common ancestor (TMRCA) for TRIM5 haplotypes yielded estimates ranging between 4 and 7 million years. Overall, these data indicate that long-term balancing selection, an extremely rare process outside MHC genes, has maintained trans-specific polymorphisms in the first intron of TRIM5. Bioinformatic analyses indicated that variants in intron 1 may affect transcription factor-binding sites and, therefore, TRIM5 transcriptional activity. Data herein confirm an extremely complex evolutionary history of TRIM5 genes in primates and open the possibility that regulatory variants in the gene modulate the susceptibility to HIV-1.

A population genetics study of the familial Mediterranean fever gene: evidence of balancing selection under an overdominance regime.

Familial Mediterranean Fever (FMF) is a recessively inherited systemic autoinflammatory disease caused by mutations in the MEFV gene. The frequency of different disease alleles is extremely high in multiple populations from the Mediterranean region, suggesting heterozygote advantage. Here, we characterize the sequence variation and haplotype structure of the MEFV 3' gene region (from exon 5 to the 3' UTR) in seven human populations. In non-African populations, we observed high levels of nucleotide variation, an excess of intermediate-frequency alleles, reduced population differentiation and a genealogy with two common haplotypes separated by deep branches. These features are suggestive of balancing selection having acted on this region to maintain one or more selected alleles. In line with this finding, an excess of heterozygotes was observed in Europeans and Asians, suggesting an overdominance regime. Our data, together with the earlier demonstration that the MEFV exon 10 has been subjected to episodic positive selection over primate evolution, provide evidence for an adaptive role of nucleotide variation in this gene region. Our data suggest that further studies aimed at clarifying the role of MEFV variants might benefit from the integration of molecular evolutionary and functional analyses.

Effect of the catechol-O-methyltransferase val(158)met genotype on children's early phases of facial stimuli processing.

The ability to process and identify human faces matures early in life, is universal and is mediated by a distributed neural system. The temporal dynamics of this cognitive-emotional task can be studied by cerebral visual event-related potentials (ERPs) that are stable from midchildhood onwards. We hypothesized that part of individual variability in the parameters of the N170, a waveform that specifically marks the early, precategorical phases of human face processing, could be associated with genetic variation at the functional polymorphism of the catechol-O-methyltransferase (val(158)met) gene, which influences information processing, cognitive control tasks and patterns of brain activation during passive processing of human facial stimuli. Forty-nine third and fourth graders underwent a task of implicit processing of other children's facial expressions of emotions while ERPs were recorded. The N170 parameters (latency and amplitude) were insensitive to the type of expression, stimulus repetition, gender or school grade. Although limited by the absence of met- homozygotes among boys, data showed shorter N170 latency associated with the presence of 1-2 met158 alleles, and family-based association tests (as implemented in the PBAT version 2.6 software package) confirmed the association. These data were independent of the serotonin transporter promoter polymorphism and the N400 waveform investigated in the same group of children in a previous study. Some electrophysiological features of face processing may be stable from midchildhood onwards. Different waveforms generated by face processing may have at least partially independent genetic architectures and yield different implications toward the understanding of individual differences in cognition and emotions.

Silencers regulate both constitutive and alternative splicing events in mammals.

Constitutive and alternative splicing events are regulated, in higher eukaryotes, by the action of multiple weak cis-acting elements and trans-acting factors. In particular, several evidences have suggested that silencers might have a fundamental role in preventing pseudoexon inclusion in mature transcripts and in defining constitutive exons by suppressing nearby decoy splice sites. Moreover, silencer elements allow the recruitment of regulatory factors to alternatively spliced exons, therefore participating in the modulation of alternative splicing pathways. Here we focus on splicing repression mechanisms in mammals, with particular concern to both exonic and intronic silencer elements, secondary structure formation and role in human genetic disease.Recently, in addition to the availability of a growing number of sequence elements deriving from the analysis of individual regulated exons, approaches have been developed that allowed the systematic identification of splicing silencers. These methods and are briefly described, as well as the motifs they retrieved, and summary of silenced exons is provided.

Trans-acting factors may cause dystrophin splicing misregulation in BMD skeletal muscles.

We analyzed dystrophin alternative splicing events in a large number of Becker muscular dystrophy (BMD) affected individuals presenting major hot-spot deletions. Evidence is shown that altered splicing patterns in these patients do not directly result from the gene defect but probably derive from modifications in trans- rather than cis-acting factors. Several potential CUG-binding protein 2 (CUG-BP2) binding sites were found to be located in the dystrophin gene region encompassing exons 43-60 and CUG-BP2 transcript analysis indicated that not only expression levels are increased in dystrophic muscles but also that different CUG-BP2 isoforms are expressed. The possibility that CUG-BP2 might have a role in dystrophin splicing regulation is discussed.

The dystrophin gene is alternatively spliced throughout its coding sequence.

We have analysed splicing patterns in the human dystrophin gene region encoding the rod and cysteine-rich domains in normal skeletal muscle, brain and heart tissues. Sixteen novel alternative transcripts were identified, the majority of them being present in all three tissues. Tissue-specific variants were also identified, suggesting a functional role of transcriptional diversity. Transcript analysis in dystrophinopathic autoptic and bioptic specimens revealed that pre-mRNAs secondary structure formation and relative strength of exon/exon association play little or no role in directing alternative splicing events. This analysis also showed that independent deletion events leading to the loss of the same exons may be associated with transcriptional variability.

Electrophysiological analysis of cognitive slowing in subjects with mitochondrial encephalomyopathy.

Mitochondrial encephalomyopathies (MEs) are multisystemic inherited disorders affecting tissues with high energy requirement such as the muscle, retina and central nervous system. Progressive external ophthalmoplegia and myopathy are the most common features in adults, and cognitive impairment is rare. In many neurodegenerative disorders, ERPs have been effectively performed to record cognitive slowing on tasks with different amount of information. To analyze the evidence for possible cognitive slowing, a standard auditory oddball paradigm with a button-press response was applied. Participants were 11 non-demented patients affected by mitochondrial encephalomyopathy and 14 age-matched normal controls. This hypothesis was tested using two tasks of different difficulty (pure tone vs. phonetic stimuli). Reaction time (RT), performance (P) and event-related potentials (ERPs) were measured. RT and P were not significantly different between the groups. Patients showed significantly increased N2 latency and reduced P3 amplitude on both tasks. No difference was found in pure tone and phonetic task conditions. Results were interpreted as electrophysiological signs of cognitive slowing--particularly in relation to stimulus evaluation--irrespective of sensory problems, response selection and cognitive load. These findings suggest that in ME patients, there may be a possible dysfunction of neural mechanisms underlying cognitive events and ERP generation.

Analysis of splicing parameters in the dystrophin gene: relevance for physiological and pathogenetic splicing mechanisms.

The molecular mechanisms that direct splice-site selection and assure orderly exon juxtaposition have not been fully clarified. The extraordinary nature of the dystrophin gene points to several hurdles in the processing of transcripts. In this study, dystrophin statistical and thermodynamic splicing parameters have been evaluated providing the first comprehensive description for a single human gene. We show that concomitant use of consensus values (CV) and DeltaDG degrees 37 values for U1snRNA annealing better discriminates between real donor sites and donor-like sequences. Evidence is also provided that, on average, out-of-frame dystrophin exons have significantly stronger CVs and more favorable DeltaDG degrees 37 values; this feature has never been reported and might reflect evolutionary-driven minimization of out-of-frame exon misplicing. Dystrophin splicing mutations have been reported to determine either Duchenne or Becker Muscular Dystrophy, but no comprehensive genotypic/phenotypic correlation has ever been investigated. We have analyzed splicing affecting single base-pair substitutions in the dystrophin gene with respect to their effect on splicing parameters; functional and clinical consequences are also reported. We have found 5'-splice-site mutation occurrence to be statistically related to mutability quotients and propose the use of DeltaDG degrees 37 values as a more effective tool than CV alone to describe donor site mutation consequences. Our analysis also indicates a nearly 100% correlation between clinical phenotype and the reading-frame rule determined at the RNA level. We consider that elucidation of the relative importance of splicing determinants might help to clarify the molecular mechanisms that direct correct splicing in complex genes and might be useful in the validation of predictive models.

Effect of sodium pool changes on blood pressure in patients undergoing PFD: design of a prospective randomized multicenter trial.

Blood pressure control is important during dialysis and the interdialytic period because of the frequency and potential seriousness of hypotension and hypertension. Water and sodium removal play an important role in the genesis of intradialytic cardiovascular instability or hypertension. Changing dialysate sodium concentrations without the aid of a kinetic model can sometimes give good results but is only an empirical approach. Therefore, this clinical trial was designed to prospectively investigate the advantages of changes in the sodium pool on the blood pressure profile of patients undergoing paired filtration dialysis (PFD). The hypothesis to be tested is whether using a dialysate conductivity which, according to the conductivity kinetic model, ensures that the conductivity of the ultrafiltrate at the end of each dialysis session is 0.3 mS/cm more (B) or less (C) than the mean during the run-in period, improves blood pressure control either in patients prone to intradialytic hypotension or patients who are hypertensive or normotensive with antihypertensive treatment. Patients will be randomly allocated to one of two treatment sequences (where treatment A is standard PFD): AABB or ABAA for patients with intradialytic hypotension; AACC or ACAA for hypertensive patients. During the experimental phase arterial blood pressure will be measured and symptoms reported by the patients will be recorded.

Evolution of ocular clinical and electrophysiological findings in pediatric Bardet-Biedl syndrome.

Bardet-Biedl syndrome (BBS) is a hereditary autosomal-recessive disorder, characterized by mental retardation, obesity, pigmentary retinopathy, polydactyly and, only in males, hypogenitalism. Even though genetic studies have revealed five different forms of BBS correlated to distinct loci on different chromosomes, a diagnosis of BBS is still primarily based on clinical data. The present study discusses the evolution of clinical ophthalmological and electrophysiological characteristics of BBS patients in developmental age. The main results obtained on a sample of 13 pediatric patients are the following: * progressive loss of visual acuity arised early in the first decade of life * ophthalmoscopic signs of pigmentary retinopathy were present only in 46% of the children studied * striking anomalies in the electroretinogram were also detected in the cases without pigmentary retinopathy * the electroretinographic results, when detectable, suggested a greater involvement of the photopic system as against the scotopic system.