You are what your mother eats: evidence for maternal preconception diet influencing foetal sex in humans

Facultative adjustment of sex ratios by mothers occurs in some animals, and has been linked to resource availability. In mammals, the search for consistent patterns is complicated by variations in mating systems, social hierarchies and litter sizes. Humans have low fecundity, high maternal investment and a potentially high differential between the numbers of offspring produced by sons and daughters: these conditions should favour the evolution of facultative sex ratio variation. Yet little is known of natural mechanisms of sex allocation in humans. Here, using data from 740 British women who were unaware of their foetus's gender, we show that foetal sex is associated with maternal diet at conception. Fifty six per cent of women in the highest third of preconceptional energy intake bore boys, compared with 45% in the lowest third. Intakes during pregnancy were not associated with sex, suggesting that the foetus does not manipulate maternal diet. Our results support hypotheses predicting investment in costly male offspring when resources are plentiful. Dietary changes may therefore explain the falling proportion of male births in industrialized countries. The results are relevant to the current debate about the artificial selection of offspring sex in fertility treatment and commercial 'gender clinics'.     

Prevalence of the 281 (Gly→Glu) mutation in hepatoerythropoietic porphyria and porphyria cutanea tarda

Summary The prevalence of the 281 (GlyGlu) mutation in hepatoerythropoietic porphyria (HEP) was investigated by the use of hybridization with a synthetic oligonucleotide probe. The mutation was found in HEP-affected members of two unrelated families from Spain, but was absent in two other patients from Italy and Portugal who also had HEP. Moreover, this mutation was not detected in 13 unrelated cases of familial (type II) porphyria cutanea tarda.     

Motor learning by observing

Learning complex motor behaviors like riding a bicycle or swinging a golf club is based on acquiring neural representations of the mechanical requirements of movement (e.g., coordinating muscle forces to control the club). Here we provide evidence that mechanisms matching observation and action facilitate motor learning. Subjects who observed a video depicting another person learning to reach in a novel mechanical environment (imposed by a robot arm) performed better when later tested in the same environment than subjects who observed similar movements but no learning; moreover, subjects who observed learning of a different environment performed worse. We show that this effect is not based on conscious strategies but instead depends on the implicit engagement of neural systems for movement planning and control.     

Detecting overlapping coding sequences in virus genomes

Background  

Detecting new coding sequences (CDSs) in viral genomes can be difficult for several reasons. The typically compact genomes often contain a number of overlapping coding and non-coding functional elements, which can result in unusual patterns of codon usage; conservation between related sequences can be difficult to interpret – especially within overlapping genes; and viruses often employ non-canonical translational mechanisms – e.g. frameshifting, stop codon read-through, leaky-scanning and internal ribosome entry sites – which can conceal potentially coding open reading frames (ORFs).     

Full development of Th2 immunity requires both innate and adaptive sources of CD154

The CD40-CD154 interaction is critical for Th2 response generation during helminth infection and following immunization with helminth-conditioned dendritic cells, yet the key cellular sources of these molecules have still to be defined in vivo. In this study, we demonstrate that the requirement for CD40 expression during murine Th2 response induction is restricted exclusively to the Ag-bearing dendritic cells. In contrast, development of full Th2 immunity required CD154 expression on multiple populations. In this respect, optimal production of IL-5, IL-10, and IL-13 was dependent upon CD154 expression by both CD4(+) T cells and non-lymphoid cells. IL-4 production had less stringent costimulatory requirements, with expression of CD154 on either non-lymphoid cells or T cells alone being sufficient to enable production of this archetypal Th2 cytokine. Disparities in CD154 requirements for T cell and B cell responses were revealed during experimental schistosomiasis where, even in the face of robust Th2 generation, B cell class-switching was entirely dependent upon expression of CD154 by the lymphoid compartment. These data help define the costimulatory interactions that occur during the generation of Th2 immunity, and challenge the widely held view that CD154 expressing T cells are the sole contributors in this process.     

The Problem of Adult Play Fighting: A Comparative Analysis of Play and Courtship in Primates

Although play fighting, like play generally, is predominantly a feature of the juvenile phase, such behavior persists in the adults of many species. There are two major contexts in which adults engage in play fighting – with juveniles and with other adults. The least attention has been given to adult–adult play. However, one pattern that has been noted by several authors is that the most commonly occurring context of adult–adult play fighting is during courtship, and that this is more likely to occur in solitary species. Supposedly, such play could function to overcome the aggressiveness of potential pairmates unfamiliar with one another, or as a means of evaluating mate quality by one or both partners. By contrasting the presence and degree of play fighting during courtship with the degree of male–female familiarity, the hypothesis that the former is influenced by the latter is tested. Data on 35 species of primates, from 15 families, were compiled from the literature and compared using a method of independent contrasts that incorporates information on phylogenetic relationships. A significant regression was found, with the degree of male–female familiarity accounting for 40% of the variance in courtship play. Therefore, our data support the hypothesis that play fighting in courtship is influenced by male–female patterns of association. However, the data also indicate that other factors must influence the occurrence of play fighting amongst adults, not only during courtship, but also in nonsexual contexts. The broader context of adult–adult play in mammals is discussed.     

Unifying Fluorescence Microscopy and Mass Spectrometry for Studying Protein Complexes in Cells

We have developed and applied a method unifying fluorescence microscopy and mass spectrometry for studying spatial and temporal properties of proteins and protein complexes in yeast cells. To combine the techniques, first we produced a variety of DNA constructs that can be used for genomic tagging of proteins with modular fluorescent and affinity tags. The modular tag consists of one of the multiple versions of monomeric fluorescent proteins fused to a variety of small affinity epitopes. After this step we tested the constructs by tagging two yeast proteins, Pil1 and Lsp1, the core components of eisosomes, the large protein complexes involved in endocytosis in Saccharomyces cerevisiae, with a variety of fluorescent and affinity probes. Among the modular tags produced we found several combinations that were optimal for determining subcellular localization and for purifying the tagged proteins and protein complexes for the detailed analysis by mass spectrometry. And finally, we applied the designed method for finding the new protein components of eisosomes and for gaining new insights into molecular mechanisms regulating eisosome assembly and disassembly by reversible phosphorylation and dephosphorylation. Our results indicate that this approach combining fluorescence microscopy and mass spectrometry into a single method provides a unique perspective into molecular mechanisms regulating composition and dynamic properties of the protein complexes in living cells.Fluorescent proteins have become invaluable probes for studying molecular processes in living cells with light microscopy techniques (1–3). Proteins, organelles, and entire cells can be selectively visualized using a variety of fluorescent proteins fused to the proteins of interest (1–6). Combined with genetics and molecular biology techniques fluorescence microscopy provides an efficient tool for observing molecular phenotypes useful for dissecting the pathways of cell cycle progression and cell response to internal and external signals (7). However, understanding the mechanism controlling the properties of proteins in cells can be a challenging task, frequently requiring a comprehensive characterization of the proteins at the molecular level.The proteins tagged with green fluorescent protein (GFP)¹ can be also purified using GFP antibodies. Cheeseman and Desai (8) and Cristea et al. (9) have enriched GFP-tagged proteins and protein complexes for further detailed analysis by MS. The MS-based methods for protein analysis are fast, sensitive, and able to identify both proteins in complex protein mixtures and residues bearing post-translational modifications (10, 11). Thus, the addition of affinity purification and mass spectrometry steps enabled the researchers to study protein interactions and the post-translational modifications in the context of the protein subcellular localization. Juxtaposition of the protein localization, composition of the protein complexes, and post-translational modifications frequently yield a unique perspective of the cellular processes and the molecular mechanisms of their regulation (12, 13).Using fluorescent proteins also as affinity probes can be problematic in several instances. First of all, the good quality antibodies against the rapidly increasing number of fluorescent proteins (3, 6) are not yet readily available. Furthermore raising antibodies specifically recognizing fluorescent proteins originating from the same organism but fluorescing a different color can be difficult or even impossible because such proteins frequently differ by mutations of only a few amino acids (1–6). Thus, we seek an alternative approach to the design of tags suitable for subcellular localization and purification of proteins and protein complexes that is 1) independent of the availability of antibody to a specific form of a fluorescent protein, 2) suitable for multiplexing, i.e. simultaneous observation of subcellular localization of several proteins and affinity purification of the proteins and stably associated protein complexes, and 3) flexible and easy to modify to incorporate better versions of fluorescent proteins and affinity tags after they are discovered.One possible solution that satisfies the stated requirements is to use a modular tag containing a version of a fluorescent protein fused to an affinity epitope. In this case we can decouple requirements for both modules and optimize the performance of each one independently for fluorescence microscopy and affinity purification experiments. To our knowledge, this possibility was first realized by Thorn and co-worker (14) who have fused 3HA (three repeats of YPYDVPDYA epitope from hemagglutinin protein) and 13MYC (13 repeats of EQKLISEEDL epitope, corresponding to a stretch of the C-terminal amino acids of the human c-MYC protein) tags to several variants of fluorescent proteins. The authors have argued that the fusion of the fluorescent proteins to the affinity epitopes may enable fluorescence and immunochemical analysis but did not test this idea. Cheeseman and Desai (8) fused the S-peptide and hexahistidine epitopes to the GFP protein to enable additional tandem purification steps. Su and co-workers (15) also fused a hexahistidine tag (His₆) to GFP to purify recombinantly produced proteins. Although hexahistidine tag performs well for isolation of overexpressed recombinant proteins, it works poorly for affinity purification of low abundance, endogenously expressed proteins (16). A double affinity tag containing a single MYC epitope and hexahistidine was also used to purify recombinantly produced fluorescent proteins (6).Here we describe the design and implementation of the modular fluorescent and affinity tags. These tags contain a variety of fluorescent proteins, which can be used exclusively for obtaining subcellular visualization, and several small epitope tags that can be utilized to perform two-step affinity purification. To test the performance of the constructs produced, we tagged two yeast proteins, Pil1 and Lsp1, the core components of eisosomes, with a variety of modular tags.Eisosomes are large heterodimeric protein complexes recently discovered in Saccharomyces cerevisiae (17). There are ∼50–100 eisosomes in each mature yeast cell distributed uniformly in a characteristic dotted pattern at the cell surface periphery. Each eisosome contains ∼2000–5000 copies of Pil1 and Lsp1. It was shown that eisosomes serve as portals of endocytosis in yeast. The function of eisosomes is regulated by reversible phosphorylation (18, 19).Among the constructs tested, we found several combinations of fluorescent protein and affinity tags that were optimal for determining subcellular localization and purification of the proteins and protein complexes. We applied these tags to further investigate eisosomes and found several new protein components of the complexes and obtained new insights into molecular mechanisms regulating eisosome integrity by reversible phosphorylation and dephosphorylation. Our results indicate that an approach combining fluorescence microscopy and mass spectrometry into a single method provides a unique perspective into molecular mechanisms regulating composition and dynamic properties of the protein complexes in living cells.     

Dictyostelium discoideum as Expression Host: Isotopic Labeling of a Recombinant Glycoprotein for NMR Studies

The advantages of the organism Dictyostelium discoideum as an expression host for recombinant glycoproteins have been exploited for the production of an isotopically labeled cell surface protein for NMR structure studies. Growth medium containing [¹⁵N]NH₄Cl and [¹³C]glycerol was used to generate isotopically labeled Escherichia coli, which was subsequently introduced to D. discoideum cells in simple Mes buffer. A variety of growth conditions were screened to establish minimal amounts of nitrogen and carbon metabolites for a cost-effective protocol. Following single-step purification by anion-exchange chromatography, 8 mg of uniformly ¹³C,¹⁵N-labeled protein secreted by approximately 10¹⁰D. discoideum cells was isolated from 3.3 liters of supernatant. Mass spectrometry showed the recombinant protein of 16 kDa to have incorporated greater than 99.9% isotopic label. The two-dimensional ¹H-¹³C HSQC spectrum confirms ¹³C labeling of both glycan and amino acid residues of the glycoprotein. All heteronuclear NMR spectra showed a good dispersion of cross-peaks essential for high-quality structure determination.     

The combined effects of energy and disturbance on species richness in protist microcosms

The supply of energy, and the frequency of disturbance can both affect species diversity, often, although not always, producing unimodal diversity patterns along an energy or disturbance gradient. However, it has been suggested that diversity is a combined function of both factors, and the dynamic equilibrium model proposed by Huston (1979) is one formalization of this suggestion. This idea has received little direct testing. Here we carry out such a test using protist microcosms, in a factorial manipulation of six levels of energy (quantity of organic resource) and five levels of disturbance (frequency of temperature shock). Species richness responded to both energy supply and disturbance frequency, although not always unimodally. Patterns of response changed over time, and there was some evidence of an interaction between energy and disturbance at two of six time intervals. However, the specific form of this interaction differs from that predicted by the dynamic equilibrium model, and overall, the results provide little support for the model.     

Purification and characterization of the FeII- and alpha-ketoglutarate-dependent xanthine hydroxylase from Aspergillus nidulans

His6-tagged xanthine/alpha-ketoglutarate (alphaKG) dioxygenase (XanA) of Aspergillus nidulans was purified from both the fungal mycelium and recombinant Escherichia coli cells, and the properties of the two forms of the protein were compared. Evidence was obtained for both N- and O-linked glycosylation on the fungus-derived XanA, which aggregates into an apparent dodecamer, while bacterium-derived XanA is free of glycosylation and behaves as a monomer. Immunological methods identify phosphothreonine in both forms of XanA, with phosphoserine also detected in the bacterium-derived protein. Mass spectrometric analysis confirms glycosylation and phosphorylation of the fungus-derived sample, which also undergoes extensive truncation at its amino terminus. Despite the major differences in the properties of these proteins, their kinetic parameters are similar (kcat = 30-70 s-1, Km of alphaKG = 31-50 muM, Km of xanthine approximately 45 muM, and pH optima at 7.0-7.4). The enzyme exhibits no significant isotope effect when [8-2H]xanthine is used; however, it demonstrates a 2-fold solvent deuterium isotope effect. CuII and ZnII potently inhibit the FeII-specific enzyme, whereas CoII, MnII, and NiII are weaker inhibitors. NaCl decreases the kcat and increases the Km of both alphaKG and xanthine. The alphaKG cosubstrate can be substituted with alpha-ketoadipate (9-fold decrease in kcat and 5-fold increase in the Km compared to those of the normal alpha-keto acid), while the alphaKG analogue N-oxalylglycine is a competitive inhibitor (Ki = 0.12 muM). No alternative purines effectively substitute for xanthine as a substrate, and only one purine analogue (6,8-dihydroxypurine) results in significant inhibition. Quenching of the endogenous fluorescence of the two enzyme forms by xanthine, alphaKG, and DHP was used to characterize their binding properties. A XanA homology model was generated on the basis of the structure of the related enzyme TauD (PDB entry 1OS7) and provided insights into the sites of posttranslational modification and substrate binding. These studies represent the first biochemical characterization of purified xanthine/alphaKG dioxygenase.