Mitochondrial respiratory activity of the trematode Fasciola hepatica

Polarographic studies have been made on the respiratory activity of isolated mitochondria of the trematode F. hepatica. Respiratory chain transferring electrons to oxygen and which is sensitive to cyanide was found in the mitochondria. Certain coupling between respiration and phosphorylation was observed. Intact mitochondria of the trematode exhibit the respiratory control although its level is significantly lower than that in the mitochondria from rat liver. The existence of an alternative respiratory chain was demonstrated in which electron transport is not associated with ATP synthesis.     

Local adaptation of the trematode Fasciola hepatica to the snail Galba truncatula

Experimental infections of six riverbank populations of Galba truncatula with Fasciola hepatica were carried out to determine if the poor susceptibility of these populations to this digenean might be due to the scarcity or the absence of natural encounters between these snails and the parasite. The first three populations originated from banks frequented by cattle in the past (riverbank group) whereas the three others were living on islet banks without any known contact with local ruminants (islet group). After their exposure, all snails were placed in their natural habitats from the end of October up to their collection at the beginning of April. Compared to the riverbank group, snails, which died without cercarial shedding clearly predominated in the islet group, while the other infected snails were few in number. Most of these last snails released their cercariae during a single shedding wave. In islet snails dissected after their death, the redial and cercarial burdens were significantly lower than those noted in riverbank G. truncatula. Snails living on these islet banks are thus able to sustain larval development of F. hepatica. The modifications noted in the characteristics of snail infection suggest the existence of an incomplete adaptation between these G. truncatula and the parasite, probably due to the absence of natural contact between host and parasite.     

Reserve nutrients of the trematode Fasciola hepatica at various stages in its ontogeny

A comparative histochemical study for the presence of reserve nutrients (glycogen, fat) in tissues, organs of parthenitae (sporocysts, rediae) and larvae (miracidia, cercariae, adolescariae) of Fasciola hepatica from liver of sheep and cattle was carried out. The glycogen amount prevails at all developmental stages of Fasciola from sheep as compared to those from cattle. Fat was found in tissues and organs of parthenitae and larvae of this trematode in equal amount. Its reserves are obviously smaller than those of glycogen.     

Genomics of reproduction in parasitic nematodes-fundamental and biotechnological implications

Understanding reproductive and developmental processes of socioeconomically important parasitic nematodes is of fundamental scientific interest and could have important implications for developing novel methods for parasite control via the disruption or interruption of such processes. Central to investigating reproductive molecular biology is the identification and characterisation of genes with sex-specific expression profiles. However, there is currently a paucity of information on such genes and their expression patterns in parasitic nematodes. This article describes recent progress on the characterisation of sex-specific genes from a parasitic nematode of veterinary importance, and discusses the fundamental scientific and applied implications of this work.     

Small peptides, big world: biotechnological potential in neglected bioactive peptides from arthropod venoms.

Until recently, a toxinologist's tasks involved the search for highly toxic or lethal toxins in animal venoms that could explain the harmful effects in clinically observed symptoms. Most of these toxins were put on evidence using a function to structure approach, in which a biological phenomena observation usually guided the isolation and characterization of the causative molecule. Paving this way, many toxins were promptly purified because of their readily observed effect. Nevertheless, small molecules with micro-effects that are not easily visualized can be relatively neglected or poorly studied. This situation has changed now with the advent of the sensitivity, resolution and accuracy of techniques such as mass spectrometry and proteomic approaches used in toxinology. Taking advantage of these methodologies, small peptides with 'newly exploited' biological activities such as vasoactive, hormone-like, antimicrobial and others have been recently given much more attention, enlarging the known repertoire of bioactive molecules found in animal venoms. This article aims to review current knowledge on small biologically active peptides (<3 kDa) found in arthropod venoms and discuss their potentialities as new drug candidates or therapeutic lead compounds.     

Ecological dynamics and biotechnological implications of thraustochytrids from marine habitats

Thraustochytrids, a group of osmoheterotrophic marine protists, have recently gained increased attention owing to their spectacular biotechnological potentials. They possess enormous capability of producing omega-3 (ω-3) polyunsaturated fatty acids (PUFAs) such as docosahexaenoic acid (DHA), eicosapentaenoic acid (EPA), and several other bioactive metabolites, known to have nutritional implications in human health. They have emerged lately as an efficient economic alternative compared with other fish and algal oil sources by virtue of their simpler PUFA profiles and cost-effective culture conditions. This review is an attempt to summarize the ecological significance of thraustochytrids with an emphasis on their cultured and uncultured diversity from various marine habitats accounted during the last few decades. Moreover, improved technologies such as media optimization in conjugation with metabolic engineering, adopted for biotechnological advancement of ω-3 products of thraustochytrids are highlighted with particular concern on the respective fatty acid biosynthetic pathways. One of the future prospects focuses on utilization of thraustochytrids for biodiesel production owing to their tremendous potentiality of yielding low carbon monounsaturated fatty acids (LC-MUFAs). However, there is utmost need of in-depth diversity assessments from various oceanic ecosystems in order to gain insight on potential thraustochytrids for ameliorated employment toward biotechnological applications.     

Toward practical, DNA-based diagnostic methods for parasitic nematodes of livestock--bionomic and biotechnological implications

Parasitic nematodes of livestock have a major economic impact worldwide. In spite of the health problems caused by nematodes and advances toward the development of vaccines and new therapeutic agents against some of them, relatively limited attention has been paid to the need for improved, practical methods of diagnosis. Accurate diagnosis and genetic characterization of parasitic nematodes of livestock are central to their effective control, particularly given the current, serious problems with anthelmintic resistance in nematode populations. Traditional diagnostic techniques have considerable limitations, and there have been some advances toward the development of molecular-diagnostic tools. This article provides a brief account of the significance of parasitic nematodes (order Strongylida), reviews the techniques that have been evaluated or used for diagnosis and describes developments in polymerase chain reaction (PCR)-based methods for the specific diagnosis of nematode infection/s and the genetic characterisation of the causative agents. The advances made in recent years provide a solid foundation for the development of practical, highly sensitive and specific diagnostic tools for epidemiological investigations and for use in control programmes.     

A portrait of the “SCP/TAPS” proteins of eukaryotes — Developing a framework for fundamental research and biotechnological outcomes

A wide range of proteins belonging to the SCP/TAPS “family” has been described for various eukaryotic organisms, including plants and animals (vertebrates and invertebrates, such as helminths). Although SCP/TAPS proteins have been proposed to play key roles in a number of fundamental biological processes, such as host–pathogen interactions and defence mechanisms, there is a paucity of information on their genetic relationships, structures and functions, and there is no standardised nomenclature for these proteins. A detailed analysis of the relationships of members of the SCP/TAPS family of proteins, based on key protein signatures, could provide a foundation for investigating these areas. In this article, we review the current state of knowledge of key SCP/TAPS proteins of eukaryotes, with an emphasis on those from parasitic helminths, and undertake a comprehensive, systematic phylogenetic analysis of currently available full-length protein sequence data (considering characteristic protein signatures or motifs) to infer relationships and provide a framework (based on statistical support) for the naming of these proteins. This framework is intended to guide genomic and molecular biological explorations of key SCP/TAPS molecules associated with infectious diseases of plants and animals. In particular, fundamental investigations of these molecules in parasites and the integration of structural and functional data could lead to new and innovative approaches for the control of parasitic diseases, with important biotechnological outcomes.     

Improved insights into the transcriptomes of the human hookworm Necator americanus--fundamental and biotechnological implications

Hookworms of humans are blood-feeding parasitic nematodes of major socio-economic significance in a wide range of countries. They cause a neglected tropical disease (NTD) called "hookworm disease" (=necatoriasis and/or ancylostomiasis). Necator americanus is the most widely distributed hookworm of humans and is a leading cause of iron deficiency anaemia, which can cause physical and mental retardation and deaths in children as well as adverse maternal-foetal outcomes. Currently, there is a significant focus on the development of new approaches for the prevention and control of hookworms in humans. Technological advances are underpinning the discovery of drug and vaccine targets through insights into the molecular biology and genomics of these parasites and their relationship with the human host. In spite of the widespread socio-economic impacts of human necatoriasis, molecular datasets for N. americanus are scant, limiting progress in molecular research. The present article explores all currently available EST datasets for adult and larval stages of N. americanus using a semi-automated bioinformatic pipeline. In the current repertoire of molecules now available, some have been or are being considered as candidate vaccines against N. americanus. Among others, the most abundant sets of molecules relate to the pathogenesis-related protein (PRP) superfamily, comprising various members, such as the Ancylostoma-secreted or activation-associated proteins (ASPs) and the kunitz-type proteins, both of which are inferred to play key roles in the interplay between N. americanus and the human host. Understanding the molecular biology of these and other novel molecules discovered could have important implications for finding new ways of disrupting the pathways that they are involved in, and should facilitate the identification of new drug and vaccine targets. Also, the bioinformatic prediction of the essentiality of genes and gene products as well as molecular network connectivity of nematode-specific genes, together with sequencing by 454 technology, are likely to assist in the genomic discovery efforts in the very near future, to also underpin fundamental, molecular research of hookworms.     

A family portrait of the RIO kinases

The RIO family of atypical serine protein kinases has been first characterized only recently. It consists of enzymes that contain a unique domain with a characteristic kinase sequence motif and usually some additional domains. At least two RIO proteins, Rio1 and Rio2, are present in organisms varying from Archaea to humans, with a third Rio3 subfamily present only in multicellular eukaryotes. Yeast Rio1 and Rio2 proteins have been implicated in the processing of 20 S pre-rRNA and are necessary for survival of the cells. Crystal structures of Archaeoglobus fulgidus Rio1 and Rio2 have shown that whereas the overall fold of these enzymes resembles typical protein kinases, some of the structural domains, particularly those involved in peptide substrate binding, are not present. The mode of binding of nucleotides also differs from that found in typical protein kinases. Although it has been shown that both Rio1 and Rio2 have the enzymatic activity of kinases and are capable of autophosphorylation, the biological substrates of RIO proteins and their full biological role still remain to be discovered.     

A portrait of the adenosine triphosphate synthetase-hydrolase

It is proposed that the ATP-synthetic and ATP-hydrolytic activities of energy-transducing mitochondria, chloroplasts and bacterial membranes are due to different enzyme systems. It is suggested that the alpha-subunits of the oligomycin-sensitive coupling factor catalyze synthesis and the beta-subunits catalyze hydrolysis. Evidence is assembled from the literature in support of this concept.