Trans-acting hepatitis delta virus ribozyme: catalytic core and global structure are dependent on the 5' substrate sequence

The hepatitis delta virus (HDV), an infectious human pathogen affecting millions of people worldwide, leads to intensified disease symptoms, including progression to liver cirrhosis upon coinfection with its helper virus, HBV. Both the circular RNA genome of HDV and its complementary antigenome contain a common cis-cleaving catalytic RNA motif, the HDV ribozyme, which plays a crucial role in viral replication. Previously, the crystal structure of the product form of the cis-acting genomic HDV ribozyme has been determined, and the precursor form has been suggested to be structurally similar. In contrast, solution studies by fluorescence resonance energy transfer (FRET) on a trans-cleaving form of the ribozyme have shown significant global conformational changes upon catalysis, while 2-aminopurine (AP) fluorescence assays have detected concomitant local conformational changes in the catalytic core. Here, we augment these studies by using terbium(III) to probe the structure of the trans-acting HDV ribozyme at nucleotide resolution. We observe significant structural differences between the precursor and product forms, especially in the P1.1 helix and the trefoil turn in the single-stranded region connecting P4 and P2 (termed J4/2) of the catalytic core. We show, using terbium(III) footprinting and sensitized luminescence spectroscopy as well as steady-state, time-resolved, and gel-mobility FRET assays on a systematic set of substrates, that the substrate sequence immediately 5' to the cleavage site significantly modulates these local as well as resultant global structural differences. Our results suggest a structural basis for the previously observed impact of the 5' substrate sequence on catalytic activity.     

Issues of cost and efficiency in the design of reliability studies

Reliability of continuous and dichotomous responses is usually assessed by means of the intraclass correlation coefficient (ICC). We derive the optimal allocation of the number of subjects k and the number of repeated measurements n that minimize the variance of the estimated ICC. Cost constraints are discussed for the case of normally distributed responses. Tables showing optimal choices of k and n are given, along with guidelines for the design of reliability studies in light of our results and those reported by others.     

Compartmentalization of Fas and Fas ligand may prevent auto- or paracrine apoptosis in epithelial cells

Oligomerization of Fas receptor by its ligand, FasL, activates a signaling cascade that leads to apoptosis of Fas bearing cells. Interestingly, many epithelia coexpress Fas and FasL, yet FasL does not trigger Fas present on the same or neighboring cells to induce spontaneous apoptosis. Here, we show that Fas and FasL are segregated from each other to different cellular compartments in kidney epithelial MDCK cells. While Fas is restricted to the basolateral surface, FasL is sequestered to an intracellular compartment and, a lesser extent, the apical surface. This spatial segregation of Fas and FasL may explain how epithelial cells can constitutively express a functional Fas pathway but avoid auto- or paracrine cell death. Compromising this spatial segregation in physiological or pathological situations may play a so far underestimated role in initiating apoptosis of epithelial cells.     

Multiple functions of tail-anchor domains of mitochondrial outer membrane proteins

Tail-anchored proteins form a distinct class of membrane proteins that have a single membrane anchor sequence at their C-terminus, the tail-anchor. Their N-terminal portion is exposed to the cytosol. We have studied the roles of tail-anchor domains of proteins residing in the mitochondrial outer membrane. Four distinct functions of the tail-anchor domain were identified. First, the domain mediates the targeting to mitochondria in a process that probably requires a net positive charge at the C-terminally flanking segment. Second, tail-anchor domains facilitate the insertion into the mitochondrial outer membrane. Third, the tail-anchor is responsible for the assembly of the respective protein into functional multi-subunit complexes; and fourth, tail-anchor domains can stabilize such complexes.     

Chromosomal and molecular characterization of Aethomys kaiseri from Zambia and Aethomys chrysophilus from Tanzania (Rodentia, Muridae)

Aethomys is a common and widespread rodent genus in the African savannas and grasslands. However, its systematics and taxonomy are still unclear as no study has covered the entire range. In fact it might not be a monophyletic genus and perhaps should be split into two subgenera, Micaelamys and Aethomys. In this paper, we present findings based on the cytogenetics and the entire cytochrome b sequence of two species from Zambia (A. kaiseri) and Tanzania (A. chrysophilus), and we compare them with the sequences of a South African species (A. namaquensis) and other allied muroid genera. Comparison of the banded chromosomes revealed complete G-band homology between the autosomes of the two species. However, the X and Y chromosomes clearly differ in size and in C- and G-banding, being much larger in A. kaiseri. Comparison of the cytochrome b sequences places the separation between A. kaiseri and A. chrysophilus at 4.49 Mya, a period of intense speciation in other African muroids. The resulting phylogeny strongly supports the idea of a paraphyletic group, suggesting the need to elevate the previously described subgenera to the genus rank.     

Progress in the development of a recombinant vaccine for human hookworm disease: the Human Hookworm Vaccine Initiative

Hookworm infection is one of the most important parasitic infections of humans, possibly outranked only by malaria as a cause of misery and suffering. An estimated 1.2 billion people are infected with hookworm in areas of rural poverty in the tropics and subtropics. Epidemiological data collected in China, Southeast Asia and Brazil indicate that, unlike other soil-transmitted helminth infections, the highest hookworm burdens typically occur in adult populations, including the elderly. Emerging data on the host cellular immune responses of chronically infected populations suggest that hookworms induce a state of host anergy and immune hyporesponsiveness. These features account for the high rates of hookworm reinfection following treatment with anthelminthic drugs and therefore, the failure of anthelminthics to control hookworm. Despite the inability of the human host to develop naturally acquired immune responses to hookworm, there is evidence for the feasibility of developing a vaccine based on the successes of immunising laboratory animals with either attenuated larval vaccines or antigens extracted from the alimentary canal of adult blood-feeding stages. The major antigens associated with each of these larval and adult hookworm vaccines have been cloned and expressed in prokaryotic and eukaryotic systems. However, only eukaryotic expression systems (e.g., yeast, baculovirus, and insect cells) produce recombinant proteins that immunologically resemble the corresponding native antigens. A challenge for vaccinologists is to formulate selected eukaryotic antigens with appropriate adjuvants in order to elicit high antibody titres. In some cases, antigen-specific IgE responses are required to mediate protection. Another challenge will be to produce anti-hookworm vaccine antigens at high yield low cost suitable for immunising large impoverished populations living in the developing nations of the tropics.     

Requirements for Cu(A) and Cu-S center assembly of nitrous oxide reductase deduced from complete periplasmic enzyme maturation in the nondenitrifier Pseudomonas putida

Bacterial nitrous oxide (N(2)O) reductase is the terminal oxidoreductase of a respiratory process that generates dinitrogen from N(2)O. To attain its functional state, the enzyme is subjected to a maturation process which involves the protein-driven synthesis of a unique copper-sulfur cluster and metallation of the binuclear Cu(A) site in the periplasm. There are seven putative maturation factors, encoded by nosA, nosD, nosF, nosY, nosL, nosX, and sco. We wanted to determine the indispensable proteins by expressing nos genes from Pseudomonas stutzeri in the nondenitrifying organism Pseudomonas putida. An in silico study of denitrifying bacteria revealed that nosL, nosX (or a homologous gene, apbE), and sco, but not nosA, coexist consistently with the N(2)O reductase structural gene and other maturation genes. Nevertheless, we found that expression of only three maturation factors (periplasmic protein NosD, cytoplasmic NosF ATPase, and the six-helix integral membrane protein NosY) together with nosRZ in trans was sufficient to produce catalytically active holo-N(2)O reductase in the nondenitrifying background. We suggest that these obligatory factors are required for Cu-S center assembly. Using a mutational approach with P. stutzeri, we also studied NosA, the Cu-containing outer membrane protein previously thought to have Cu insertase function, and ScoP, a putative membrane-anchored chaperone for Cu(A) metallation. Both of these were found to be dispensable elements for N(2)O reductase biosynthesis. Our experimental and in silico data were integrated in a model of N(2)O reductase maturation.     

Role for the BRCA1 C-terminal repeats (BRCT) protein 53BP1 in maintaining genomic stability

p53-binding protein-1 (53BP1) is phosphorylated in response to DNA damage and rapidly relocalizes to presumptive sites of DNA damage along with Mre11 and the phosphorylated histone 2A variant, gamma-H2AX. 53BP1 associates with the BRCA1 tumor suppressor, and knock-down experiments with small interfering RNA have revealed a role for the protein in the checkpoint response to DNA damage. By generating mice defective in m53BP1 (m53BP1(tr/tr)), we have created an animal model to further explore its biochemical and genetic roles in vivo. We find that m53BP1(tr/tr) animals are growth-retarded and show various immune deficiencies including a specific reduction in thymus size and T cell count. Consistent with a role in responding to DNA damage, we find that m53BP1(tr/tr) mice are sensitive to ionizing radiation (gamma-IR), and cells from these animals exhibit chromosomal abnormalities consistent with defects in DNA repair. Thus, 53BP1 is a critical element in the DNA damage response and plays an integral role in maintaining genomic stability.