Modeling of human cytomegalovirus maternal-fetal transmission in a novel decidual organ culture

Human cytomegalovirus (HCMV) is the leading cause of congenital infection, associated with severe birth defects and intrauterine growth retardation. The mechanism of HCMV transmission via the maternal-fetal interface is largely unknown, and there are no animal models for HCMV. The initial stages of infection are believed to occur in the maternal decidua. Here we employed a novel decidual organ culture, using both clinically derived and laboratory-derived viral strains, for the ex vivo modeling of HCMV transmission in the maternal-fetal interface. Viral spread in the tissue was demonstrated by the progression of infected-cell foci, with a 1.3- to 2-log increase in HCMV DNA and RNA levels between days 2 and 9 postinfection, the expression of immediate-early and late proteins, the appearance of typical histopathological features of natural infection, and dose-dependent inhibition of infection by ganciclovir and acyclovir. HCMV infected a wide range of cells in the decidua, including invasive cytotrophoblasts, macrophages, and endothelial, decidual, and dendritic cells. Cell-to-cell viral spread was revealed by focal extension of infected-cell clusters, inability to recover infectious extracellular virus, and high relative proportions (88 to 93%) of cell-associated viral DNA. Intriguingly, neutralizing HCMV hyperimmune globulins exhibited inhibitory activity against viral spread in the decidua even when added at 24 h postinfection-providing a mechanistic basis for their clinical use in prenatal prevention. The ex vivo-infected decidual cultures offer unique insight into patterns of viral tropism and spread, defining initial stages of congenital HCMV transmission, and can facilitate evaluation of the effects of new antiviral interventions within the maternal-fetal interface milieu.     

Using DNA microarrays to study natural variation

The emerging field of genomics examines the relationship between genetic and phenotypic variation by describing and analyzing patterns of natural variation on a genome-wide scale. In this endeavor, an important tool is the use of microarrays, which enable simultaneous screening of thousands of assays. Microarrays were originally designed for the detection of differences between samples and are thus ideally suited to high-throughput studies of natural variation. Novel microarray platforms enable the high throughput survey of variation at multiple levels, including DNA sequences, gene expression, protein binding, and methylation. However, most microarray data analysis tools, notably normalization methods, were developed for experiments in which only few features differed between samples. In studies of natural variation, this assumption does not always hold, raising a number of new challenges.     

ATM-mediated phosphorylation of polynucleotide kinase/phosphatase is required for effective DNA double-strand break repair

The cellular response to double-strand breaks (DSBs) in DNA is a complex signalling network, mobilized by the nuclear protein kinase ataxia-telangiectasia mutated (ATM), which phosphorylates many factors in the various branches of this network. A main question is how ATM regulates DSB repair. Here, we identify the DNA repair enzyme polynucleotide kinase/phosphatase (PNKP) as an ATM target. PNKP phosphorylates 5'-OH and dephosphorylates 3'-phosphate DNA ends that are formed at DSB termini caused by DNA-damaging agents, thereby regenerating legitimate ends for further processing. We establish that the ATM phosphorylation targets on human PNKP-Ser 114 and Ser 126-are crucial for cellular survival following DSB induction and for effective DSB repair, being essential for damage-induced enhancement of the activity of PNKP and its proper accumulation at the sites of DNA damage. These findings show a direct functional link between ATM and the DSB-repair machinery.     

Relationship between Antibody 2F5 Neutralization of HIV-1 and Hydrophobicity of Its Heavy Chain Third Complementarity-Determining Region

The membrane-proximal external region (MPER) of the HIV-1 gp41 transmembrane glycoprotein is the target of the broadly neutralizing antibody 2F5. Prior studies have suggested a two-component mechanism for 2F5-mediated neutralization involving both structure-specific recognition of a gp41 protein epitope and nonspecific interaction with the viral lipid membrane. Here, we mutationally alter a hydrophobic patch on the third complementarity-determining region of the heavy chain (CDR H3) of the 2F5 antibody and assess the abilities of altered 2F5 variants to bind gp41 and to neutralize diverse strains of HIV-1. CDR H3 alterations had little effect on the affinity of 2F5 variants for a peptide corresponding to its gp41 epitope. In contrast, strong effects and a high degree of correlation (P < 0.0001) were found between virus neutralization and CDR H3 hydrophobicity, as defined by predicted free energies of transfer from water to a lipid bilayer interface or to octanol. The effect of CDR H3 hydrophobicity on neutralization was independent of isolate sensitivity to 2F5, and CDR H3 variants with tryptophan substitutions were able to neutralize HIV-1 ∼10-fold more potently than unmodified 2F5. A threshold was observed for increased hydrophobicity of the 2F5 CDR H3 loop beyond which effects on 2F5-mediated neutralization leveled off. Together, the results provide a more complete understanding of the 2F5 mechanism of HIV-1 neutralization and indicate ways to enhance the potency of MPER-directed antibodies.The membrane-proximal external region (MPER) of the human immunodeficiency virus type 1 (HIV-1) gp41 transmembrane glycoprotein is the target of three broadly neutralizing anti-HIV-1 antibodies, 2F5, Z13e, and 4E10, and is thus a potential site of HIV-1 vulnerability to the humoral immune response (21, 24, 27, 48). The MPER encompasses ∼25 residues at the carboxyl-terminal end of the predicted gp41 ectodomain, just before the transmembrane region, and is rich in aromatic residues, typical of bilayer-interfacial regions of membrane proteins (26, 36, 40). Mutation of selected MPER tryptophans abrogates gp41-mediated fusion of the viral and target cell membranes, indicating that this region is crucial for HIV-1 infectivity (23, 28). Structural studies of unbound forms of the gp41 MPER both in solution and in lipid contexts have demonstrated that it adopts a number of conformations, many of which are α-helical, and electron-paramagnetic resonance measurements have indicated lipid bilayer immersion depths for MPER residues that range from acyl to phospholipid headgroup regions (4, 7, 8, 19, 32, 37). The binding of neutralizing antibodies, such as 2F5, to the MPER must therefore account for the membrane milieu in which the epitope is found.The 2F5 antibody has been shown to exhibit ∼100-fold-enhanced binding to its epitope on uncleaved gp140s when presented in the context of lipid proteoliposomes (11, 25), and other studies have shown that 2F5 can contact phospholipids directly in the absence of gp41 (1, 3, 12, 22, 29, 30). The latter finding has led to the suggestion that 2F5 might be autoreactive (12), although passive transfusion of 2F5 does not appear to have deleterious effects (38) and 2F5 failed to react in some clinically based assays for autoreactive lipid antibodies (31, 39). The crystal structures of the 2F5 antibody in complex with its gp41 MPER epitope revealed that, despite the 22-residue length of the 2F5 heavy chain third complementarity-determining region (CDR H3) loop, contacts with the gp41 MPER peptide are made predominantly at the loop base. In some crystal structures, the tip of the loop protrudes away from gp41, while in others, it is disordered (9, 14, 25). A unique feature of the tip of the CDR H3 loop is that it contains a patch of hydrophobic residues, including residues L100_A, F100_B, V100_D, and I100_F (Kabat numbering), which, with the exception of I100_F, do not contact gp41 (9, 10, 14, 25) (Fig. ​(Fig.1).1). While a prior study revealed the importance of residue F100_B of the CDR H3 loop in 2F5-neutralizing activity, nonconservative residue substitutions at this position also appeared to diminish 2F5 binding to the immobilized MPER peptide and gp41 in enzyme-linked immunosorbent assay (ELISA) formats (47). Conversely, a more recent study has shown that alanine mutations in the 2F5 CDR H3 loop can affect neutralization without affecting gp41 binding (2).Open in a separate windowFIG. 1.2F5 CDR H3 loop mutagenesis. (A) Structure of 2F5 Fab (blue and gray) in complex with a gp41 peptide (red). The 2F5 CDR H3 (purple) contacts gp41 only at its base, while the tip extends away from the peptide. (B) Close-up view of the 2F5 CDR H3 loop, with hydrophobic residues at the loop tip shown in stick representation and colored green. (C) Mutations introduced into the tip of the 2F5 CDR H3 (100_A to 100_F) are defined, along with a plot of the Wimley-White predicted free energies of transfer to a lipid bilayer interface (black) or to octanol (gray) for each of the mutations.In this study, we sought to examine the role of the chemical nature of residues at the tip of the 2F5 CDR H3 loop in neutralization of HIV-1. Mutations were introduced into the 2F5 CDR H3 loop that altered its hydrophobicity, and the resulting 2F5 mutants were tested both for binding to a gp41 epitope peptide and for neutralization of HIV-1. The results showed that the tip of the 2F5 CDR H3 loop, and specifically its hydrophobic nature, is required for 2F5-mediated neutralization of HIV-1 by means that appear to be independent both of gp41 affinity and of isolate-specific sensitivity to neutralization by 2F5.     

The TRAPP complex is a nucleotide exchanger for Ypt1 and Ypt31/32

In yeast, the Ypt1 GTPase is required for ER-to-cis-Golgi and cis-to-medial-Golgi protein transport, while Ypt31/32 are a functional pair of GTPases essential for exit from the trans-Golgi. We have previously identified a Ypt1 guanine nucleotide exchange factor (GEF) activity and characterized it as a large membrane-associated protein complex that localizes to the Golgi and can be extracted from the membrane by salt, but not by detergent. TRAPP is a large protein complex that is required for ER-to-Golgi transport and that has properties similar to those of Ypt1 GEF. Here we show that TRAPP has Ypt1 GEF activity. GST-tagged Bet3p or Bet5p, two of the TRAPP subunits, were expressed in yeast cells and were precipitated by glutathione-agarose (GA) beads. The resulting precipitates can stimulate both GDP release and GTP uptake by Ypt1p. The majority of the Ypt1 GEF activity associated with the GST-Bet3p precipitate has an apparent molecular weight of > 670 kDa, indicating that the GEF activity resides in the TRAPP complex. Surprisingly, TRAPP can also stimulate nucleotide exchange on the Ypt31/32 GTPases, but not on Sec4p, a Ypt-family GTPase required for the last step of the exocytic pathway. Like the previously characterized Ypt1 GEF, the TRAPP Ypt1-GEF activity can be inhibited by the nucleotide-free Ypt1-D124N mutant protein. This mutant protein also inhibits the Ypt32 GEF activity of TRAPP. Coprecipitation and overexpression studies suggest that TRAPP can act as a GEF for Ypt1 and Ypt31/32 in vivo. These data suggest the exciting possibility that a GEF complex common to Ypt1 and Ypt31/32 might coordinate the function of these GTPases in entry into and exit from the Golgi.     

Factors that control the efficacy of group Ia synapses in alpha-motoneurons

1.) This review considers factors that produce systematic variations in the amplitude of monosynaptic group Ia EPSPs in triceps surae alpha-motoneurons belonging to different motor unit types. 2.) Anatomical studies using horseradish peroxidase to label functionally-identified group Ia afferents and motoneurons postsynaptic to them, and combined anatomicalelectro-physiological studies of type-identified alpha-motoneurons, have constrained some of the factors that produce variations in peak Ia EPSP amplitude in different cells. 3.) Computer modeling studies based on these experimental data, together with other evidence in the literature, suggest that the major factor that produces systematic variation in Ia EPSP amplitudes in type FF, FR, and S motoneurons is a corresponding variation in the density of active group Ia synapses. 4.) Although EPSP amplitudes are also affected by the relative conductance of the somatic membrane, as reflected in the dendritic-to-somatic conductance ratio, it is possible that at least some of this influence is an artifact produced by microelectrode penetration.     

The natural variation of a neural code

The way information is represented by sequences of action potentials of spiking neurons is determined by the input each neuron receives, but also by its biophysics, and the specifics of the circuit in which it is embedded. Even the "code" of identified neurons can vary considerably from individual to individual. Here we compared the neural codes of the identified H1 neuron in the visual systems of two families of flies, blow flies and flesh flies, and explored the effect of the sensory environment that the flies were exposed to during development on the H1 code. We found that the two families differed considerably in the temporal structure of the code, its content and energetic efficiency, as well as the temporal delay of neural response. The differences in the environmental conditions during the flies' development had no significant effect. Our results may thus reflect an instance of a family-specific design of the neural code. They may also suggest that individual variability in information processing by this specific neuron, in terms of both form and content, is regulated genetically.     

Evolution of bitter taste receptors in humans and apes

Bitter taste perception is crucial for the survival of organismsbecause it enables them to avoid the ingestion of potentiallyharmful substances. Bitter taste receptors are encoded by agene family that in humans has been shown to contain 25 putativelyfunctional genes and 8 pseudogenes and in mouse 33 putativelyfunctional genes and 3 pseudogenes. Lineage-specific expansionsof bitter taste receptors have taken place in both mouse andhuman, but very little is known about the evolution of thesereceptors in primates. We report the analysis of the almostcomplete repertoires of bitter taste receptor genes in human,great apes, and two Old World monkeys. As a group, these genesseem to be under little selective constraint compared with olfactoryreceptors and other genes in the studied species. However, incontrast to the olfactory receptor gene repertoire, where humanshave a higher proportion of pseudogenes than apes, there isno evidence that the rate of loss of bitter taste receptor genesvaries among humans and apes.