Ancestral exonic organization of FUT8, the gene encoding the alpha6-fucosyltransferase, reveals successive peptide domains which suggest a particular three-dimensional core structure for the alpha6-fucosyltransferase family

Based on PCR strategies and expression studies, we define the genomic organization of the FUT8b gene. This gene encodes the only known mammalian enzyme transferring fucose in an alpha1-->6 linkage on the asparagine-branched GlcNAc residue of the chitobiose unit of complex N:-glycans. The intron/exon organization of the bovine coding sequence determines five successive functional domains. The first exon encodes a domain homologous to cytoskeleton proteins, the second presents a proline-rich region including a motif XPXPPYXP similar to the peptide ligand of the SH3-domain proteins, the third encodes a gyrase-like domain (an enzyme which can bind nucleotides), and the fourth encodes a peptide sequence homologous to the catalytic domain of proteins transferring sugars. Finally, the last exon encodes a domain homologous to the SH3 conserved motif of the SH2-SH3 protein family. This organization suggests that intramolecular interactions might give a tulip-shaped scaffolding, including the catalytic pocket of the enzyme in the Golgi lumen. Deduced from the published sequence of chromosome 14 (AL109847), the human gene organization of FUT8 seems to be similar to that of bovine FUT8b, although the exon partition is more pronounced (bovine exons 1 and 2 correspond to human exons 1-6). The mosaicism and phylogenetic positions of the alpha6-fucosyltransferase genes are compared with those of other fucosyltransferase genes.     

Tracing genetic history of modern humans using X-chromosome lineages

Genetic variability of the compound interrupted microsatellite DXS1238, in intron 44 of the dystrophin gene, provides evidence for a complex structure of the ancestral population that led to the emergence of modern humans. We sequenced DXS1238 in 600 X-chromosomes from all over the world. Forty four percent of African-specific chromosomes belong to the ancestral lineage that did not participate in the out-of-Africa expansion and subsequent colonization of other continents. Based on the coalescence analysis these lineages separated from those that contributed to the out-of-Africa expansion 366 ± 136 thousands years ago (Kya). Independently, the analysis of the variance in the repeat length and of the decay of the ancestral alleles of the two DXS1238 repeats, GT and GA, dates this separation at more than 200 Kya. This suggests a complex demographic history and genetic structure of the African melting pot that led to the emergence of modern humans and their out-of-Africa migration. The subsequent subdivisions of human populations among different continents appear to be preceded by even more structured population history within Africa itself, which resulted from a restricted gene flow between lineages allowing for genetic differences to accumulate. If the transition to modern humans occurred during that time, it necessarily follows that genes associated with this transformation spread between subpopulations via gene flow. Otherwise, in spite of subsequent anatomical variation, Homo sapiens as a species could have emerged in Africa already between 300 and 200 Kya, i.e. before the mitochondrial DNA and well before the Y-chromosome most recent common ancestors. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

High selfing and high inbreeding depression in peripheral populations of Juncus atratus

The mating system of a plant is the prime determinant of its population genetic structure. However, mating system effects may be modified by postzygotic mechanisms like inbreeding depression. Furthermore, historical as well as contemporary ecological factors and population characteristics, like the location within the species range can contribute to genetic variability. Using microsatellite markers we assessed the population genetic structure of the wind-pollinated Juncus atratus in 16 populations from peripheral and nearly central areas of the distribution range and studied the mating system of the species. In three peripheral populations, outcrossing rates at seeds stage were low (mean t(m) = 5.6%), suggesting a highly autogamous mating system. Despite this fact, on adult stage both individual heterozygosity (mean H(O) = 0.48) and gene diversity (mean H(E) = 0.58) were high even in small populations. Inbreeding coefficients were consistently low among all populations (mean F(IS) = 0.15). Within the three peripheral populations indirect estimates of lifetime inbreeding depression were surprisingly high (delta(eq) = 0.96) and inbreeding depression could be shown to act mostly on early seedling establishment. Similar conditions of autogamy combined with high inbreeding depression are typical for plants with a large lifetime genomic mutation rate that cannot avoid selfing by geitonogamy. However, the results presented here are unexpected for small-statured, herbaceous plants. Substantial genetic differentiation among all populations was found (mean F(ST) = 0.24). An isolation-by-distance pattern was apparent on large scale but not on local scale suggesting that the overall pattern was largely influenced by historical factors, e.g. colonization, whereas locally genetic drift was of greater importance than gene flow. Peripheral populations exhibited lower genetic diversity and higher inbreeding coefficients when compared with subcentral populations.     

X-treme loss of sequence diversity linked to neo-X chromosomes in filarial nematodes

The sequence diversity of natural and laboratory populations of Brugia pahangi and Brugia malayi was assessed with Illumina resequencing followed by mapping in order to identify single nucleotide variants and insertions/deletions. In natural and laboratory Brugia populations, there is a lack of sequence diversity on chromosome X relative to the autosomes (π_X/π_A = 0.2), which is lower than the expected (π_X/π_A = 0.75). A reduction in diversity is also observed in other filarial nematodes with neo-X chromosome fusions in the genera Onchocerca and Wuchereria, but not those without neo-X chromosome fusions in the genera Loa and Dirofilaria. In the species with neo-X chromosome fusions, chromosome X is abnormally large, containing a third of the genetic material such that a sizable portion of the genome is lacking sequence diversity. Such profound differences in genetic diversity can be consequential, having been associated with drug resistance and adaptability, with the potential to affect filarial eradication.     

O-linked N-acetylglucosaminylation is involved in the Ca2+ activation properties of rat skeletal muscle

O-Linked N-acetylglucosaminylation termed O-GlcNAc is a dynamic cytosolic and nuclear glycosylation that is dependent both on glucose flow through the hexosamine biosynthesis pathway and on phosphorylation because of the existence of a balance between phosphorylation and O-GlcNAc. This glycosylation is a ubiquitous post-translational modification, which probably plays an important role in many aspects of protein functions. We have previously reported that, in skeletal muscle, proteins of the glycolytic pathway, energetic metabolism, and contractile proteins were O-GlcNAc-modified and that O-Glc-NAc variations could control the muscle protein homeostasis and be implicated in the regulation of muscular atrophy. In this paper, we report O-N-acetylglucosaminylation of a number of key contractile proteins (i.e. myosin heavy and light chains and actin), which suggests that this glycosylation could be involved in skeletal muscle contraction. Moreover, our results showed that incubation of skeletal muscle skinned fibers in N-acetyl-d-glucosamine, in a concentration solution known to inhibit O-GlcNAc-dependent interactions, induced a decrease in calcium sensitivity and affinity of muscular fibers, whereas the cooperativity of the thin filament proteins was not modified. Thus, our results suggest that O-GlcNAc is involved in contractile protein interactions and could thereby modulate muscle contraction.     

Profiling of membrane proteins from human macrophages: comparison of two approaches

Macrophages are involved in various important biological processes and their functions are tightly regulated. Hydrophobic proteins are difficult to analyse by 2-DE because of their intrinsic tendency to self-aggregate during the first dimension (IEF). We have compared two protocols for extracting, separating and identifying membrane proteins from human macrophages by MALDI-TOF MS. The first protocol used protein extraction by solvent, followed by 2-DE and allowed us to identify 10% membrane proteins among the proteins identified a being like the peroxisome-activated receptor delta. The second method is based on solubilizing the membranes with Triton X-100, separating the proteins by anion-exchange chromatography followed by SDS-PAGE. This method allowed us to identify 49 membrane proteins, including four integral membrane proteins, ten type I, two type II and one type III membrane proteins. Several receptors were identified, including integrin alpha-3 and ephrin type A receptor 7. Interestingly, several proteins involved in macrophage functions were identified, such as integrin alpha-X and macrophage mannose receptor. These findings show that techniques are available to identify membrane proteins, but that they require large quantities of cells which means that they are not suitable for the limiting amounts of precious samples available from clinical studies.     

Microinjection of recombinant O-GlcNAc transferase potentiates Xenopus oocytes M-phase entry

In order to understand the importance of the cytosolic and nuclear-specific O-linked N-acetylglucosaminylation (O-GlcNAc) on cell cycle regulation, we recently reported that inhibition of O-GlcNAc transferase (OGT) delayed or blocked Xenopus laevis oocyte germinal vesicle breakdown (GVBD). Here, we show that increased levels of the long OGT isoform (ncOGT) accelerate X. laevis oocyte GVBD. A N-terminally truncated isoform (sOGT) with a similar in vitro catalytic activity towards a synthetic CKII-derived peptide had no effect, illustrating the important role played by the N-terminal tetratrico-peptide repeats. ncOGT microinjection in the oocytes increases both the speed and extent of O-GlcNAc addition, leads to a quicker activation of the MPF and MAPK pathways and finally results in a faster GVBD. Microinjection of anti-OGT antibodies leads to a delay of the GVBD kinetics. Our results hence demonstrate that OGT is a key molecule for the timely progression of the cell cycle.