The RecB protein of Escherichia coli translocates along single-stranded DNA in the 3′ to 5′ direction: a proposed ratchet mechanism

To investigate the role that the individual subunits play in the ATP-dependent helicase activity of the RecBCD protein we have investigated the ability of the RecB, RecC and RecD proteins to displace various 20-mer oligonucleotides annealed to either end or to the centre of an oligonucleotide 60 bases long. The results show that the only subunit which can displace the 20-mers in the absence of the other subunits is the RecB protein. Moreover, the 20-mer is displaced only if it is annealed to the 60-mer at the 5′ end or the middle, suggesting that the RecB protein translocates along the 60-mer in the 3′ to 5′ direction, displacing annealed 20-mers as it proceeds. We have shown that reconstituted RecBC and RecBCD complexes displace the 20-mers but, unlike RecB, they do not require a 3′-ended single-stranded region for helicase action, but can displace the 20-mers from either end of the 60-mer. The level of helicase activity of the RecBC complex is considerably greater than that of RecB alone, and the activity of the RecBCD complex appears to be greater still. This hierarchy of activity is also shown by DNA binding studies, but is not reflected in the ATPase activities of the enzymes. We have also shown that the ability of trypsin to cleave various sites on the RecB molecule is modified by the presence of ATP or ATP-γ-S, suggesting that conformational changes may be induced in RecB upon ATP binding. We discuss a model for the ATP-driven, unidirectional motion of the RecB translocase along single-stranded DNA. In this model, the RecB molecule binds to single-stranded DNA and then translocates along it, one base at a time, in the 3′ to 5′ direction, by a `ratchet' mechanism in which repeated stretching and contraction of the protein is coupled to ATP hydrolysis. The RecC protein in the RecBC complex is proposed to act as a `sliding clamp' which increases processivity by preventing dissociation.     

Complete nucleotide sequence of the Escherichia coli ptr gene encoding protease III.

The nucleotide sequence of a 3120 bp region of the E. coli chromosome that includes the entire ptr gene has been determined. The proposed coding region for Protease III is 2889 nucleotides long, which would encode a protein consisting of 962 amino acids with a calculated molecular mass of 107,719 daltons. The predicted primary structure of the protein includes a 23-residue signal sequence, cleavage of which would give rise to a mature protein of molecular mass 105,124 daltons. At its 3' end, the ptr gene overlaps the start of the recB coding sequence by 8 bases, suggesting that these genes may form part of an operon.     

Induction of a protective response in mice by the dengue virus NS3 protein using DNA vaccines

The dengue non-structural 3 (NS3) is a multifunctional protein, containing a serino-protease domain, located at the N-terminal portion, and helicase, NTPase and RTPase domains present in the C-terminal region. This protein is considered the main target for CD4+ and CD8+ T cell responses during dengue infection, which may be involved in protection. However, few studies have been undertaken evaluating the use of this protein as a protective antigen against dengue, as well as other flavivirus. In the present work, we investigate the protective efficacy of DNA vaccines based on the NS3 protein from DENV2. Different recombinant plasmids were constructed, encoding either the full-length NS3 protein or only its functional domains (protease and helicase), fused or not to a signal peptide (t-PA). The recombinant proteins were successfully expressed in transfected BHK-21 cells, and only plasmids encoding the t-PA signal sequence mediated protein secretion. Balb/c mice were immunized with the different DNA vaccines and challenged with a lethal dose of DENV2. Most animals immunized with plasmids encoding the full-length NS3 or the helicase domain survived challenge, regardless of the presence of the t-PA. However, some mice presented clinical signs of infection with high morbidity (hind leg paralysis and hunched posture), mainly in animal groups immunized with the DNA vaccines based on the helicase domain. On the other hand, inoculation with plasmids encoding the protease domain did not induce any protection, since mortality and morbidity rates in these mouse groups were similar to those detected in the control animals. The cellular immune response was analyzed by ELISPOT with a specific-CD8+ T cell NS3 peptide. Results revealed that the DNA vaccines based on the full-length protein induced the production of INF-γ, thus suggesting the involvement of this branch of the immune system in the protection.     

Cloning of the uvrD gene of E. coli and identification of the product

The uvrD gene has been cloned from Escherichia coli chromosomal DNA into phage lambda, cosmid, and low-copy-number plasmid vectors. Comparison of the proteins encoded by the cloned fragments with those encoded by fragments in which the uvrD gene is inactivated by transposon insertion or by deletion shows that the uvrD gene product is a protein of Mr = 73000.     

The influence of historical climate changes on Southern Ocean marine predator populations: a comparative analysis

The Southern Ocean ecosystem is undergoing rapid physical and biological changes that are likely to have profound implications for higher‐order predators. Here, we compare the long‐term, historical responses of Southern Ocean predators to climate change. We examine palaeoecological evidence for changes in the abundance and distribution of seabirds and marine mammals, and place these into context with palaeoclimate records in order to identify key environmental drivers associated with population changes. Our synthesis revealed two key factors underlying Southern Ocean predator population changes; (i) the availability of ice‐free ground for breeding and (ii) access to productive foraging grounds. The processes of glaciation and sea ice fluctuation were key; the distributions and abundances of elephant seals, snow petrels, gentoo, chinstrap and Adélie penguins all responded strongly to the emergence of new breeding habitat coincident with deglaciation and reductions in sea ice. Access to productive foraging grounds was another limiting factor, with snow petrels, king and emperor penguins all affected by reduced prey availability in the past. Several species were isolated in glacial refugia and there is evidence that refuge populations were supported by polynyas. While the underlying drivers of population change were similar across most Southern Ocean predators, the individual responses of species to environmental change varied because of species specific factors such as dispersal ability and environmental sensitivity. Such interspecific differences are likely to affect the future climate change responses of Southern Ocean marine predators and should be considered in conservation plans. Comparative palaeoecological studies are a valuable source of long‐term data on species’ responses to environmental change that can provide important insights into future climate change responses. This synthesis highlights the importance of protecting productive foraging grounds proximate to breeding locations, as well as the potential role of polynyas as future Southern Ocean refugia.     

Expression profiling of the solute carrier gene family in chicken intestine from the late embryonic to early post-hatch stages

Intestinal development during late embryogenesis and early post-hatch has a long-term influence on digestive and absorptive capacity in chickens. The objective of this research was to obtain a global view of intestinal solute carrier (SLC) gene family member expression from late embryogenesis until 2 weeks post-hatch with a focus on SLC genes involved in uptake of sugars and amino acids. Small intestine samples from male chicks were collected on embryonic days 18 (E18) and 20 (E20), day of hatch and days 1, 3, 7 and 14 post-hatch. The expression profiles of 162 SLC genes belonging to 41 SLC families were determined using Affymetrix chicken genome microarrays. The majority of SLC genes showed little or no difference in level of expression during E18–D14. A number of well-known intestinal transporters were upregulated between E18 and D14 including the amino acid transporters rBAT , y ⁺ LAT-2 and EAAT3 , the peptide transporter PepT1 and the sugar transporters SGLT1 , GLUT2 and GLUT5 . The amino acid transporters CAT-1 and CAT-2 were downregulated. In addition, several glucose and amino acid transporters that are novel to our understanding of nutrient absorption in the chicken intestine were discovered through the arrays ( SGLT6 , SNAT1 , SNAT2 and AST ). These results represent a comprehensive characterization of the expression profiles of the SLC family of genes at different stages of development in the chicken intestine and lay the ground work for future nutritional studies.     

Eimeria species and genetic background influence the serum protein profile of broilers with coccidiosis

Background

Coccidiosis is an intestinal disease caused by protozoal parasites of the genus Eimeria. Despite the advent of anti-coccidial drugs and vaccines, the disease continues to result in substantial annual economic losses to the poultry industry. There is still much unknown about the host response to infection and to date there are no reports of protein profiles in the blood of Eimeria-infected animals. The objective of this study was to evaluate the serum proteome of two genetic lines of broiler chickens after infection with one of three species of Eimeria.

Methodology/Principal Findings

Birds from lines A and B were either not infected or inoculated with sporulated oocysts from one of the three Eimeria strains at 15 d post-hatch. At 21 d (6 d post-infection), whole blood was collected and lesion scoring was performed. Serum was harvested and used for 2-dimensional gel electrophoresis. A total of 1,266 spots were quantitatively assessed by densitometry. Protein spots showing a significant effect of coccidia strain and/or broiler genetic line on density at P<0.05−0.01 (250 spots), P<0.01−0.001 (248 spots), and P<0.001 (314 spots) were excised and analyzed by matrix-assisted laser desorption/ionization tandem time-of-flight mass spectrometry. Proteins were identified in 172 spots. A total of 46 different proteins were identified. Of the spots with a corresponding protein identification, 57 showed a main effect of coccidia infection and/or 2-way interaction of coccidia infection×broiler genetic line at P<0.001.

Conclusions/Significance

Several of the metabolic enzymes identified in this study are potential candidates for early diagnostic markers of E. acervulina infection including malate dehydrogenase 2, NADH dehydrogenase 1 alpha subcomplex 9, and an ATP synthase. These proteins were detected only in Line A birds that were inoculated with E. acervulina. Results from this study provide a basic framework for future research aimed at uncovering the complex biochemical mechanisms involved in host response to Eimeria infection and in identifying molecular targets for diagnostic screening and development of alternative preventative and therapeutic methods.