Male mating behaviour of a molly, <Emphasis Type="Italic">Poecilia latipunctata</Emphasis>: a third host for the sperm-dependent Amazon molly, <Emphasis Type="Italic">Poecilia formosa</Emphasis>

The Tamesí molly, Poecilia latipunctata, has a very limited biogeographical range in northeast Mexico. This area is nested within the ranges of the Atlantic molly, Poecilia mexicana, and the unisexual Amazon molly, Poecilia formosa. Based on morphology, especially fin shape, the Tamesí molly has been considered to be a "short-fin" molly. We describe the courtship sequence of P. latipunctata. The courtship clearly places the species into the clade of "long-fin" mollies, a finding that corroborates earlier studies based on nuclear DNA and mitochondrial DNA. All three species live together in certain habitats. This renders P. latipunctata a potential host species for the sperm-dependent, unisexual Amazon molly. Using behavioural tests, we demonstrate that P. latipunctata males actually copulate with Amazon mollies, despite a pronounced preference for conspecific females. In laboratory experiments P. latipunctata males are capable of triggering embryogenesis in P. formosa females. Field observations support the hypothesis that P. latipunctata is a third host species for P. formosa, indicating that the Amazon molly effectively exploits all available host species for its gynogenetic mode of reproduction. Electronic Publication     

DEFOG: a practical scheme for deciphering families of genes

We developed a novel efficient scheme, DEFOG (for "deciphering families of genes"), for determining sequences of numerous genes from a family of interest. The scheme provides a powerful means to obtain a gene family composition in species for which high-throughput genomic sequencing data are not available. DEFOG uses two key procedures. The first is a novel algorithm for designing highly degenerate primers based on a set of known genes from the family of interest. These primers are used in PCR reactions to amplify the members of the gene family. The second combines oligofingerprinting of the cloned PCR products with clustering of the clones based on their fingerprints. By selecting members from each cluster, a low-redundancy clone subset is chosen for sequencing. We applied the scheme to the human olfactory receptor (OR) genes. OR genes constitute the largest gene superfamily in the human genome, as well as in the genomes of other vertebrate species. DEFOG almost tripled the size of the initial repertoire of human ORs in a single experiment, and only 7% of the PCR clones had to be sequenced. Extremely high degeneracies, reaching over a billion combinations of distinct PCR primer pairs, proved to be very effective and yielded only 0.4% nonspecific products.     

Phosphatidylinositol-3,5-Bisphosphate is a potent and selective inhibitor of acid sphingomyelinase

Acid sphingomyelinase (A-SMase, EC 3.1.4.12) catalyzes the lysosomal degradation of sphingomyelin to phosphorylcholine and ceramide. Inherited deficiencies of acid sphingomyelinase activity result in various clinical forms of Niemann-Pick disease, which are characterised by massive lysosomal accumulation of sphingomyelin. Sphingomyelin hydrolysis by both, acid sphingomyelinase and membrane-associated neutral sphingomyelinase, plays also an important role in cellular signaling systems regulating proliferation, apoptosis and differentiation. Here, we present a potent and selective novel inhibitor of A-SMase, L-alpha-phosphatidyl-D-myo-inositol-3,5-bisphosphate (PtdIns3,5P2), a naturally occurring substance detected in mammalian, plant and yeast cells. The inhibition constant Ki for the new A-SMase inhibitor PtdIns3,5P2 is 0.53 microM as determined in a micellar assay system with radiolabeled sphingomyelin as substrate and recombinant human A-SMase purified from insect cells. Even at concentrations of up to 50 microM, PtdIns3,5P2 neither decreased plasma membrane-associated, magnesium-dependent neutral sphingomyelinase activity, nor was it an inhibitor of the lysosomal hydrolases beta-hexosaminidase A and acid ceramidase. Other phosphoinositides tested had no or a much weaker effect on acid sphingomyelinase. Different inositol-bisphosphates were studied to elucidate structure-activity relationships for A-SMase inhibition. Our investigations provide an insight into the structural features required for selective, efficient inhibition of acid sphingomyelinase and may also be used as starting point for the development of new potent A-SMase inhibitors optimised for diverse applications.     

Ethical and regulatory issues arising from proteomic research and technology

Over the last two decades, medical research has begun to make extensive use of products of human origin in therapeutics, oncology, and most recently, in genetic diseases. This has raised many ethical issues involving patient rights, including issues of consent. Besides informed consent, researchers should address several topics when designing studies using human tissues. Reward for the patient should be kept minimal. Sample transfer should be organized along non-profit lines, at least in Europe. Sampling procedures should be at no risk for human volunteers, and at minimal risk for patients. Biosafety aspects should be addressed, in particular when international collaborations are intended or when collaboration is existing between academia and industry. Regulations on importation and exportation of human tissues should be observed. Data acquisition and storage should be addressed in accordance with national data protection regulations, in particular when using computerized databases. If follow-up information is to be taken, the authorization for such information should be requested. The right for patient's information (or for no information) on the research results should also be addressed. The issues of validation and patenting should be also solved, usually by informing the patient that he/she will have no commercial rights on potential research results. The patient should be told if the samples are transferred to another research laboratory or private company. Samples and related data should be destroyed on request at any time point during the course of the study. If possible, traceability of the donor should be ensured.     

Improved proteome analysis of Saccharomyces cerevisiae mitochondria by free-flow electrophoresis

The analysis of complex cellular proteomes by means of two-dimensional gel electrophoresis (2-DE) is significantly limited by the power of resolution of this technique. Although subcellular fractionation can be a fundamental first step to increase resolution, it frequently leads to preparations contaminated with other cellular structures. Here, we chose mitochondria of Saccharomyces cerevisiae to demonstrate that an integrated zone-electrophoretic purification step (ZE), with a free-flow electrophoresis device (FFE), can assist in overcoming this problem, while significantly improving their degree of purity. Whereas mitochondrial preparations isolated by means of differential centrifugation include a considerable degree of non-mitochondrial proteins (16%), this contamination could be effectually removed by the inclusion of a ZE-FFE purification step (2%). This higher degree of purity led to the identification of many more proteins from ZE-FFE purified mitochondrial protein extracts (n = 129), compared to mitochondrial protein extracts isolated by differential centrifugation (n = 80). Moreover, a marked decrease of degraded proteins was found in the ZE-FFE purified mitochondrial protein extracts. It is noteworthy that even at a low 2-DE resolution level, a four-fold higher number (17 versus 4) of presumably low abundance proteins could be identified in the ZE-FFE purified mitochondrial protein extracts. Therefore these results represent a feasible approach for an in-depth proteome analysis of mitochondria and possibly other organelles.     

Analysis of the transforming growth factor-beta1 (TGF-beta1) codon 25 gene polymorphism by LightCycler-analysis in patients with chronic hepatitis C infection

The polymorphism at position 25 of the gene encoding transforming growth factor-beta1 (TGF-beta1), which changes the amino acid sequence of the signal peptide sequence (arginine to proline), is causing a variation in TGF-beta1 production. The homozygous genotype (Arg25Arg) is associated with higher TGF-beta1 production than the heterozygous (Arg25Pro) genotype. Therefore, the possible involvement of this genetic variation in the TGF-beta1 gene for induction and progression of various diseases is under close investigation. At present, several labor-intensive established assays ranging from amplification refractory mutation system (ARMS)-PCR methodologies, sequence specific oligonucleotide probing (SSOP), restriction fragment length polymorphism (RFLP) analysis, 5' nuclease assays, and specialized fingerprinting protocols are applied to analyze the polymorphism in question. We developed a novel approach for analyzing this polymorphism in a LightCycler system and determined the allele frequency distributions between patients with different degrees of hepatic fibrosis induced by chronic hepatitis C virus infection. In patients with severe hepatic fibrosis (METAVIR-score 3-4), the Pro25 allele was twice as frequent compared to patients with mild fibrosis (METAVIR-score 0-2). However, we found no association of necroinflammatory activity and genotype distribution. This suggests that the stage of hepatic fibrosis, rather than the grade (inflammation), is influenced by the presence of proline at codon 25 in patients with chronic hepatitis C.     

Mass-Based Fraction Collection of Crude Synthetic Peptides in Analytical and Preparative Scale

Synthetic peptides become more and more important as drug candidates in the treatment of a variety of diseases. A particular therapeutic focus for synthetic peptides is cancer treatment.^1,2 In order to keep pace with the growing number of newly synthesized peptides, peptide purification should not represent the bottleneck in the drug discovery process. Since the target masses of synthetic peptides are well known, mass-based fraction collection represents an efficient technique for their purification. In contrast to fraction triggering with less specific detectors, employing a mass selective detector leads in each run only to the purification of the target mass. Consequently, it is not necessary to pick the compound of interest out of a series of redundant fractions. In this article we demonstrate mass-based purification of a variety of crude synthetic peptides by reversed phase high-performance liquid chromatography. The peptides were in the mass range from less than 1 kDa to more than 10 kDa and covered a pI range from 4 to 13. We particularly focused on some technical aspects of the system that were prerequisite for reliable compound purification with high recoveries.     

The promoter of the spinach PsaF gene for the subunit III of the photosystem I reaction center directs beta-glucuronidase gene expression in transgenic tobacco roots. Implication of the involvement of phospholipases and protein kinase C in PsaF gene expression

PsaF is a nuclear encoded gene for the subunit III of photosystem I. It is located at the lumenal side of the thylakoid membrane and interacts with plastocyanin. Starting from a low-level expression in the cotyledons of etiolated seedlings the gene is upregulated by light. Light can be replaced by Ca2+ or phosphoinositides like phorbol myristate acetate, an analogue of diacylglycerol. We tested the effects of these components on PsaF promoter-driven gene expression in roots and found that the PsaF promoter includes a positive regulatory region [-220/-179] activated by cytokinin and a negative regulatory region [-687/-221] activated by abscisic acid. In addition, the promoter is activated by Ca2+, mastoparan and phorbol myristate acetate which suggests a role for phospholipases and protein kinase C in PsaF gene expression.     

Comparative modelling of human PHOSPHO1 reveals a new group of phosphatases within the haloacid dehalogenase superfamily

PHOSPHO1 is a recently identified phosphatase whose expression is upregulated in mineralizing cells and is implicated in the generation of inorganic phosphate for matrix mineralization, a process central to skeletal development. The enzyme is a member of the haloacid dehalogenase (HAD) superfamily of magnesium-dependent hydrolases. However, the natural substrate(s) is as yet unidentified and to date no structural information is known. We have identified homologous proteins in a number of species and have modelled human PHOSPHO1 based upon the crystal structure of phosphoserine phosphatase (PSP) from Methanococcus jannaschii. The model includes the catalytic Mg(2+) atom bound via three conserved Asp residues (Asp32, Asp34 and Asp203); O-ligands are also provided by a phosphate anion and two water molecules. Additional residues involved in PSP-catalysed hydrolysis are conserved and are located nearby, suggesting both enzymes share a similar reaction mechanism. In PHOSPHO1, none of the PSP residues that confer the enzyme's substrate specificity (Arg56, Glu20, Met43 and Phe49) are conserved. Instead, we propose that two fully conserved Asp residues (Asp43 and Asp123), not present in PSPs contribute to substrate specificity in PHOSPHO1. Our findings show that PHOSPHO1 is not a member of the subfamily of PSPs but belongs to a novel, closely related enzyme group within the HAD superfamily.