Jose M. Vidal-Taboada

Identification of proteomic differences in asthenozoospermic sperm samples

BACKGROUND Asthenozoospermia is one of the most common findings present in infertile males, but its aetiology remains unknown in most cases. Present proteomic tools now offer the opportunity to identify proteins which are differentially expressed in asthenozoospermic semen samples and potentially involved in infertility. METHODS We compared the expression of 101 sperm protein spots in 20 asthenozoospermic samples to that of 10 semen donor controls using two-dimensional proteomic analysis. RESULTS Seventeen protein spots have been identified at different amounts in the asthenozoospermic samples compared with controls. These are cytoskeletal actin-B, annexin-A5, cytochrome C oxidase-6B, histone H2A, prolactin-inducible protein and precursor, calcium binding protein-S100A9 (2 spots), clusterin precursor, dihydrolipoamide dehydrogenase precursor, fumarate hydratase precursor, heat shock protein-HSPA2, inositol-1 monophosphatase, 3-mercapto-pyruvate sulfurtransferase/dienoyl-CoA isomerase precursor, proteasome subunit-PSMB3, semenogelin 1 precursor and testis expressed sequence 12. The detected amount of these proteins enabled the grouping of asthenozoospermic sperm samples in an unsupervised clustering analysis. CONCLUSIONS We have identified several proteins present at different amount in asthenozoospermic sperm samples. These proteins could be candidates towards the development of diagnostic markers, and open up the opportunity to gain further insight into the pathogenic mechanisms involved in asthenozoospermia.

A common protamine 1 promoter polymorphism (-190 C->A) correlates with abnormal sperm morphology and increased protamine P1/P2 ratio in infertile patients.

It is known that targeting the protamine 1 gene in mice leads to infertility, abnormal chromatin packaging, and abnormal sperm morphology. Because many infertile patients also have an abnormal sperm morphology and chromatin packaging, the human protamine 1 gene (PRM1) is an important candidate to screen for potential mutations. In this work, we have screened the PRM1 gene in search of potential mutations and determined the sperm morphology and the ratio between protamine 1 and protamine 2 (P1/P2 ratio). Direct sequencing of the PRM1 promoter led to the identification of a common single-nucleotide polymorphism (SNP; -190 C-->A). The -190 AA genotype was detected at a higher frequency (13.8%) in patients with markedly altered sperm morphology (<or=9% normal forms) compared with other patients (4.5%; P < .05) or compared with controls (2.97%; P < .005). The allelic frequency of the PRM1 -190 C-->A change was also consistently higher (.331) in infertile patients with a markedly altered morphology compared with population controls (.178; P < .01). Additionally, we have determined that the P1/P2 ratio is significantly increased in patients with the PRM1 -190 AA genotype compared with patients with the CA or CC genotypes (P = .006, Mann-Whitney). These findings indicate that the common PRM1 -190 C-->A polymorphism identified is associated with abnormal sperm head morphology and abnormal P1/P2 ratio in infertile patients.

Polymorphisms, haplotypes and mutations in the protamine 1 and 2 genes

Protamines are the most abundant nuclear proteins and alterations in their expression have been described in infertile patients. Also, protamine haplo-insufficient mice have been described as infertile. Therefore, the protamine 1 and 2 genes have been considered important candidates in different mutational studies. In this article, we review all published articles related to protamine gene mutations and report new data on mutations from patients and controls drawn from the Spanish and Swedish populations. Sequencing of the protamine 1 and 2 genes in a total of 209 infertile patients and 152 fertility-proven controls from the Spanish and Swedish populations identified two novel and rare non-pathogenic missense mutations (R17C and R38M) in the protamine 1 gene and several additional polymorphisms. Furthermore, we have identified and we report for the first time five novel rare haplotypes encompassing the protamine 1 and 2 genes. A review of all available protamine gene mutational studies indicates that none of the reported missense mutations can be considered of proven pathogenicity. However, it is interesting to note that rare protamine 1 promoter variants have been reported only in infertile patients, but not in fertile control groups. Pathogenic high penetrance protamine gene missense mutations, if any, must be extremely rare. However, the detected presence of rare variants and haplotypes in infertile patients deserves further investigation.

CX3CR1 Is a Modifying Gene of Survival and Progression in Amyotrophic Lateral Sclerosis

The objective of this study was to investigate the association of functional variants of the human CX3CR1 gene (Fractalkine receptor) with the risk of Amyotrophic Lateral Sclerosis (ALS), the survival and the progression rate of the disease symptoms in a Spanish ALS cohort. 187 ALS patients (142 sporadic [sALS] and 45 familial) and 378 controls were recruited. We investigated CX3CR1 V249I (rs3732379) and T280M (rs3732378) genotypes and their haplotypes as predictors of survival, the progression rate of the symptoms (as measured by ALSFRS-R and FVC decline) and the risk of suffering ALS disease. The results indicated that sALS patients with CX3CR1 249I/I or 249V/I genotypes presented a shorter survival time (42.27±4.90) than patients with 249V/V genotype (67.65±7.42; diff −25.49 months 95%CI [−42.79,−8.18]; p = 0.004; adj-p = 0.018). The survival time was shorter in sALS patients with spinal topography and CX3CR1 249I alleles (diff = −29.78 months; 95%CI [−49.42,−10.14]; p = 0.003). The same effects were also observed in the spinal sALS patients with 249I–280M haplotype (diff = −27.02 months; 95%CI [−49.57, −4.48]; p = 0.019). In the sALS group, the CX3CR1 249I variant was associated with a faster progression of the disease symptoms (OR = 2.58; 95IC% [1.32, 5.07]; p = 0.006; adj-p = 0.027). There was no evidence for association of these two CX3CR1 variants with ALS disease risk. The association evidenced herein is clinically relevant and indicates that CX3CR1 could be a disease-modifying gene in sALS. The progression rate of the diseases symptoms and the survival time is affected in patients with one or two copies of the CX3CR1 249I allele. The CX3CR1 is the most potent ALS survival genetic factor reported to date. These results reinforce the role of the immune system in ALS pathogenesis.

C/EBPβ and C/EBPδ transcription factors: Basic biology and roles in the CNS

CCAAT/enhancer binding protein (C/EBP) β and C/EBPδ are transcription factors of the basic-leucine zipper class which share phylogenetic, structural and functional features. In this review we first describe in depth their basic molecular biology which includes fascinating aspects such as the regulated use of alternative initiation codons in the C/EBPβ mRNA. The physical interactions with multiple transcription factors which greatly opens the number of potentially regulated genes or the presence of at least five different types of post-translational modifications are also remarkable molecular mechanisms that modulate C/EBPβ and C/EBPδ function. In the second part, we review the present knowledge on the localization, expression changes and physiological roles of C/EBPβ and C/EBPδ in neurons, astrocytes and microglia. We conclude that C/EBPβ and C/EBPδ share two unique features related to their role in the CNS: whereas in neurons they participate in memory formation and synaptic plasticity, in glial cells they regulate the pro-inflammatory program. Because of their role in neuroinflammation, C/EBPβ and C/EBPδ in microglia are potential targets for treatment of neurodegenerative disorders. Any strategy to reduce C/EBPβ and C/EBPδ activity in neuroinflammation needs to take into account its potential side-effects in neurons. Therefore, cell-specific treatments will be required for the successful application of this strategy.

SPG11 compound mutations in spastic paraparesis with thin corpus callosum

Background: Autosomal recessive hereditary spastic paraparesis with thin corpus callosum (ARHSP-TCC) is being increasingly recognized as a variety of spastic paraplegia with mental retardation. SPG11 gene mutations have been reported to be associated with ARHSP-TCC. Methods: As an independent group, we investigated SPG11 gene involvement in four individuals not previously described with either recessive or sporadic HSP-TCC presentation. Results: Chromosome 15q13-15 segregating autosomal disease haplotypes were different across the kindreds and sequencing of SPG11 identified four novel frameshift/nonsense segregating mutations and the R2034X mutation, which were in heterozygous compound status. The affected examined had decreased thalamic and bilateral paracentral frontal lobe metabolism on 18F-flurodeoxyglucose PET. Conclusions: Loss-of-function SPG11 mutations are the major cause of autosomal recessive hereditary spastic paraparesis with thin corpus callosum in Southern Europe, even in apparently sporadic cases. Decreased thalamic metabolism was consistently a phenotypical SPG11 mutation hallmark.

Characterisation and expression analysis of the WDR9 gene, located in the Down critical region-2 of the human chromosome 21.

We report the isolation and characterisation of the gene WDR9 (WD Repeat 9), located in the Down Syndrome critical region-2 (DCR-2) from the human chromosome 21. This gene spans 125 kb of genomic sequence and is organised in 41 exons and 40 introns. The WDR9 cDNA has a size of 13 kb and encodes for a putative protein of 2269 amino acids with a potential location in the nucleus. Expression analysis in different human adult tissues and in cultured cell lines indicates that the gene has several tissue-specific transcripts. The more significant protein signatures in the WDR9 protein sequence are for WD repeats, bromodomain, beta-ketoacyl synthases, and ribonucleoprotein (RNP). The WDR9 protein has a high similarity with the Mus musculus neuronal differentiation protein (NDRP) and a region of similarity with the region of the Yotiao protein that has been proposed to bind the NR1 subunit of the NMDA receptor. The presence of protein-protein interaction domains as such the WD repeats, and the similarity of the WDR9 protein to regulatory proteins suggest a potential involvement in some of the clinical features associated to the DCR-2.

Astroglia-Microglia Cross Talk during Neurodegeneration in the Rat Hippocampus

Brain injury triggers a progressive inflammatory response supported by a dynamic astroglia-microglia interplay. We investigated the progressive chronic features of the astroglia-microglia cross talk in the perspective of neuronal effects in a rat model of hippocampal excitotoxic injury. N-Methyl-D-aspartate (NMDA) injection triggered a process characterized within 38 days by atrophy, neuronal loss, and fast astroglia-mediated S100B increase. Microglia reaction varied with the lesion progression. It presented a peak of tumor necrosis factor-α (TNF-α) secretion at one day after the lesion, and a transient YM1 secretion within the first three days. Microglial glucocorticoid receptor expression increased up to day 5, before returning progressively to sham values. To further investigate the astroglia role in the microglia reaction, we performed concomitant transient astroglia ablation with L-α-aminoadipate and NMDA-induced lesion. We observed a striking maintenance of neuronal death associated with enhanced microglial reaction and proliferation, increased YM1 concentration, and decreased TNF-α secretion and glucocorticoid receptor expression. S100B reactivity only increased after astroglia recovery. Our results argue for an initial neuroprotective microglial reaction, with a direct astroglial control of the microglial cytotoxic response. We propose the recovery of the astroglia-microglia cross talk as a tissue priority conducted to ensure a proper cellular coordination that retails brain damage.

Molecular Mechanisms of Acute Brain Injury and Ensuing Neurodegeneration

Injury to the central nervous system (CNS), including stroke, traumatic brain injury and spinal cord injury, cause devastating and irreversible damage and loss of function. For example, stroke affects very large patient populations, results in major suffering for the patients and their relatives, and involves a significant cost to society. CNS damage implies disruption of the intricate internal circuits involved in cognition, the sensory-motor functions, and other important functions. There are currently no treatments available to properly restore such lost functions. New therapeutic proposals will emerge from an understanding of the interdependence of molecular and cellular responses to CNS injury, in particular the inhibitory mechanisms that block regeneration and those that enhance neuronal plasticity.

Microglia, Calcification and Neurodegenerative Diseases

1.1 Neurodegeneration involve different cell types Neurodegeneration is a complex process involving different cell types and neurotransmitters. A common characteristic of neurodegenerative disorders such as Alzheimer’s disease (AD), Parkinson’s disease (PD), multiple sclerosis, Huntington’s disease (HD) and Amyotrophic Lateral Sclerosis (ALS) is the occurrence of a neuroinflammatory reaction in which cellular processes involving glial cells (mainly microglia and astrocytes) and T cells are activated in response to neuronal death. This inflammatory reaction has recently received attention as an unexpected potential target for the treatment of these diseases. Microglial cells have a mesenchymal origin, invade the central nervous system (CNS) prenatally (Chan et al., 2007b) and are the resident macrophages in the CNS (Ransohoff & Perry, 2009). They comprise approximately 10-20% of adult glia and serve as the CNS innate immune system. In neurodegenerative diseases, microglia is activated by misfolded proteins. In the case of AD, amyloid-┚ (A┚) peptides accumulate extracellularly and activate the microglia locally. In the case of PD, ALS and HD, the misfolded proteins accumulate intracellularly but are still associated with activation of the microglia (Perry et al., 2010). Reactive microglia in the substantia nigra and striatum of PD brains have been described, and increased levels of proinflammatory cytokines and inducible nitric oxide synthase have been detected in these brain regions, providing evidence of a local inflammatory reaction (Hirsch & Hunot, 2009). The injection of lipopolysaccharide (a potent microglia activator) into the substantia nigra produces microglial activation and the death of dopaminergic cells. These findings support the hypothesis that microglial activation and neuroinflammation contribute to PD pathogenesis (Herrera et al., 2000). Astrocytes are ectodermal cells, and they are probably about ten times as numerous as neurons. Astroglial cells were initially believed to be passive support cells providing trophic support for surrounding neurons (Sofroniew & Vinters, 2010), maintaining extracellular ion homeostasis and capturing excess extracellular neurotransmitters such as glutamate, which is considered particularly important given its involvement in excitotoxicity. However, recent studies have implicated astrocytes in many complex CNS functions, such as physical