The Wolff-Parkinson-White Pattern in Routine Electrocardiography

Fifteen thousand consecutive electrocardiograms on R.C.A.F. aircrew applicants aged 18 to 24 were studied from the standpoint of incidence, clinical findings and follow-up of the WPW pattern discovered because the ECG was taken as part of the selection procedure. Forty-six cases were discovered (0.3%). All were reviewed and passed as clinically fit except for one with asymptomatic rheumatic heart disease. Two others gave a history suggestive of paroxysmal rapid heart action. None of the 43 men on follow-up have developed evidence of arrhythmia. Thirteen of the 46 showed an intermittent pattern initially or on subsequent follow-up. Fifty to 80% of people with the WPW pattern experience tachycardia, according to the literature. The incidence of tachycardia in this study was much lower (2 in 46 or 4.3%). The WPW pattern is not synonymous with the WPW syndrome, and iatrogenic heart disease must be avoided in fit young men in whom the WPW pattern is discovered because of routine electrocardiography.     

Advances in the development of Salmonella-based vaccine strategies for protection against Salmonellosis in humans

Salmonella spp. are important human pathogens globally causing millions of cases of typhoid fever and non-typhoidal salmonellosis annually. There are only a few vaccines licensed for use in humans which all target Salmonella enterica serovar Typhi. Vaccine development is hampered by antigenic diversity between the thousands of serovars capable of causing infection in humans. However, a number of attenuated candidate vaccine strains are currently being developed. As facultative intracellular pathogens with multiple systems for transporting effector proteins to host cells, attenuated Salmonella strains can also serve as ideal tools for the delivery of foreign antigens to create multivalent live carrier vaccines for simultaneous immunization against several unrelated pathogens. Further, the ease with which Salmonella can be genetically modified and the extensive knowledge of the virulence mechanisms of this pathogen means that this bacterium has often served as a model organism to test new approaches. In this review we focus on (1) recent advances in live attenuated Salmonella vaccine development, (2) improvements in expression of foreign antigens in carrier vaccines and (3) adaptation of attenuated strains as sources of purified antigens and vesicles that can be used for subunit and conjugate vaccines or together with attenuated vaccine strains in heterologous prime-boosting immunization strategies. These advances have led to the development of new vaccines against Salmonella which have or will soon be tested in clinical trials.     

Recurrent sublethal warming reduces embryonic survival,inhibits juvenile growth,and alters species distribution projections under climate change

The capacity to tolerate climate change often varies across ontogeny in organisms with complex life cycles. Recently developed species distribution models incorporate traits across life stages; however, these life‐cycle models primarily evaluate effects of lethal change. Here, we examine impacts of recurrent sublethal warming on development and survival in ecological projections of climate change. We reared lizard embryos in the laboratory under temperature cycles that simulated contemporary conditions and warming scenarios. We also artificially warmed natural nests to mimic laboratory treatments. In both cases, recurrent sublethal warming decreased embryonic survival and hatchling sizes. Incorporating survivorship results into a mechanistic species distribution model reduced annual survival by up to 24% compared to models that did not incorporate sublethal warming. Contrary to models without sublethal effects, our model suggests that modest increases in developmental temperatures influence species ranges due to effects on survivorship.     

WAERNIA MIRABILIS GEN. NOV., SP. NOV. (DUMONTIACEAE,GIGARTINALES): A NEW NONCORALLINE CRUSTOSE RED ALGA FROM THE NORTHWESTERN ATLANTIC OCEAN AND ITS RELATIONSHIP TO GAINIA AND BLINKSIA1

Waernia mirabilis Wilce, Maggs et Sears, gen. et sp. nov., is described for an encrusting red alga endemic to the northeastern North Atlantic Ocean. Its perennial thalli form major understory populations that may outcompete Corallinaceae and Hildenbrandiaceae in some habitats. Crustose red algae with isomorphic gametophytes and tetrasporophytes other than Corallinaceae are poorly known; Waernia differs vegetatively and reproductively from any other such algae. Gametangia are similar to those of the monotypic uncalcified crustose genera Blinksia and Gainia endemic to the Antarctic and central coastal California, respectively. Comparison of Waernia with type material of Blinksia californica Abbott & Hollenberg and Gainia mollis Moe shows that it differs from Blinksia in lacking cohesive crusts in which adjacent cells cohere by direct fusions and by its strongly recurved, rather than straight, carpogonial branches. Gainia and Waernia both have strongly recurved carpogonial branches and laxly constructed crusts that lack secondary pit connections. Gainia differs from Waernia in its considerably larger and thicker crusts, non‐nemathecial tetrasporangia, shorter carpogonial branches, and its consistently single gonimoblast initial. We continue to recognize the family Blinksiaceae as a probable member of the Gigartinales with uncertain affinities. Waernia is assigned to the Dumontiaceae (Gigartinales), as its first described isomorphic crustose member. It is also the only genus and one of few algal species endemic to northeastern North America. Waernia either arrived at its present distribution via migration from a Tertiary polar ocean or evolved from an unknown ancestor in a newly formed boreal northwest Atlantic Ocean during post‐Oligocene millennia.     

Discovery of a novel species,Theileria haneyi n. sp., infective to equids,highlights exceptional genomic diversity within the genus Theileria: implications for apicomplexan parasite surveillance

A novel apicomplexan parasite was serendipitously discovered in horses at the United States – Mexico border. Phylogenetic analysis based on 18S rDNA showed the erythrocyte-infective parasite to be related to, but distinct from, Theileria spp. in Africa, the most similar taxa being Theileria spp. from waterbuck and mountain zebra. The degree of sequence variability observed at the 18S rDNA locus also suggests the likely existence of additional cryptic species. Among described species, the genome of this novel equid Theileria parasite is most similar to that of Theileria equi, also a pathogen of horses. The estimated divergence time between the new Theileria sp. and T. equi, based on genomic sequence data, is greater than 33?million years. Average protein sequence divergence between them, at 23%, is greater than that of Theileria parva and Theileria annulata proteins, which is 18%. The latter two represent highly virulent Theileria spp. of domestic cattle, as well as of African and Asian wild buffalo, respectively, which differ markedly in pathology, host cell tropism, tick vector and geographical distribution. The extent of genome-wide sequence divergence, as well as significant morphological differences, relative to T. equi justify the classification of Theileria sp. as a new taxon. Despite the overall genomic divergence, the nine member equi merozoite antigen (EMA) superfamily, previously found as a multigene family only in T. equi, is also present in the novel parasite. Practically, significant sequence divergence in antigenic loci resulted in this undescribed Theileria sp. not being detectable using currently available diagnostic tests. Discovery of this novel species infective to equids highlights exceptional diversity within the genus Theileria, a finding with serious implications for apicomplexan parasite surveillance.     

Molecular Evolution of the Pathogenicity Island of Enterotoxigenic Bacteroides fragilis Strains

Enterotoxigenic Bacteroides fragilis (ETBF) strains, which produce a 20-kDa zinc metalloprotease toxin (BFT), have been associated with diarrheal disease in animals and young children. Studying a collection of ETBF and nontoxigenic B. fragilis (NTBF) strains, we found that bft and a second metalloprotease gene (mpII) are contained in an approximately 6-kb pathogenicity island (termed B. fragilis pathogenicity island or BfPAI) which is present exclusively in all 113 ETBF strains tested (pattern I). Of 191 NTBF strains, 100 (52%) lack both the BfPAI and at least a 12-kb region flanking BfPAI (pattern II), and 82 of 191 NTBF strains (43%) lack the BfPAI but contain the flanking region (pattern III). The nucleotide sequence flanking the left end of the BfPAI revealed a region with the same organization as the mobilization region of the 5-nitroimidazole resistance plasmid pIP417 and the clindamycin resistance plasmid pBFTM10, that is, two mobilization genes (bfmA and bfmB) organized in one operon and a putative origin of transfer (oriT) located in a small, compact region. The region flanking the right end of the BfPAI contains a gene (bfmC) whose predicted protein shares significant identity to the TraD mobilization proteins encoded by plasmids F and R100 from Escherichia coli. Nucleotide sequence analysis of one NTBF pattern III strain (strain I-1345) revealed that bfmB and bfmC are adjacent to each other and separated by a 16-bp GC-rich sequence. Comparison of this sequence with the appropriate sequence of ETBF strain 86-5443-2-2 showed that in this ETBF strain the 16-bp sequence is replaced by the BfPAI. This result defined the BfPAI as being 6,036 bp in length and its precise integration site as being between the bfmB and bfmC stop codons. The G+C content of the BfPAI (35%) and the flanking DNA (47 to 50%) differ greatly from that reported for the B. fragilis chromosome (42%), suggesting that the BfPAI and its flanking region are two distinct genetic elements originating from very different organisms. ETBF strains may have evolved by horizontal transfer of these two genetic elements into a pattern II NTBF strain.     

Characterization of an aerated submerged hollow fiber ultrafiltration device for efficient microalgae harvesting

The present work characterizes a submerged aerated hollow fiber polyvinylidene fluorid (PVDF) membrane (0.03 μm) device (Harvester) designed for the ultrafiltration (UF) of microalgae suspensions. Commercial baker''s yeast served as model suspension to investigate the influence of the aeration rate of the hollow fibers on the critical flux (CF, J _c) for different cell concentrations. An optimal aeration rate of 1.25 vvm was determined. Moreover, the CF was evaluated using two different Chlorella cultures (axenic and non‐axenic) of various biomass densities (0.8–17.5 g DW/L). Comparably high CFs of 15.57 and 10.08 L/m/²/h were measured for microalgae concentrations of 4.8 and 10.0 g DW/L, respectively, applying very strict CF criteria. Furthermore, the J _c‐values correlated (negative) linearly with the biomass concentration (0.8–10.0 g DW/L). Concentration factors between 2.8 and 12.4 and volumetric reduction factors varying from 3.5 to 11.5 could be achieved in short‐term filtration, whereat a stable filtration handling biomass concentrations up to 40.0 g DW/L was feasible. Measures for fouling control (aeration of membrane fibers, periodic backflushing) have thus been proven to be successful. Estimations on energy consumption revealed very low energy demand of 17.97 kJ/m³ treated microalgae feed suspension (4.99 × 10⁻³ kWh/m³) and 37.83 kJ/kg treated biomass (1.05 × 10⁻² kWh/kg), respectively, for an up‐concentration from 2 to 40 g DW/L of a microalgae suspension.