A Statistical Comparison between Less and Common Applied Models to Estimate Geographical Distribution of Endangered Species (<Emphasis Type="Italic">Felis margarita</Emphasis>) in Central Iran

Species distribution in space is important in habitat conservation and biodiversity protection, so gaining knowledge about species range would be worthwhile to rescue endangered species and plan conservation policy. This study evaluates and compares the performance of an array of Species Distribution Models (SDMs), namely RF, SVM, MaxEnt, GLMNET, and MARS, in predicting rare sand cat distribution across a large unprotected sand dune area in central Iran. Due to absence of reliable data and difficulties in recording the species itself, the SDMs were challenged by limited data including 55 absence (background) and 40 presence points as well as nine climatic and geological parameters that influence on species distribution, including humidity, maximum, minimum and mean temperature, precipitation, amount of sunshine, ground water level, aspect, and DEM. Moreover, each model was replicated 20 times and the statistics including TSS, AUC, COR and Deviance were computed. Then, based on computed statistics, the model performances were evaluated by TUKEY and ANOVA. Finally, ensemble map was obtained by weighted approach using AUC. The results of this study showed that complex machine learning methods, like SVM, RF, and MaxEnt are more outperformed to predict the distribution of rare species.     

Hexokinase Binding to Mitochondria: A Basis for Proliferative Energy Metabolism

Current thought is that proliferating cells undergo a shift from oxidative to glycolytic metabolism, where the energy requirements of the rapidly dividing cell are provided by ATP from glycolysis. Drawing on the hexokinase–mitochondrial acceptor theory of insulin action, this article presents evidence suggesting that the increased binding of hexokinase to porin on mitochondria of cancer cells not only accelerates glycolysis by providing hexokinase with better access to ATP, but also stimulates the TCA cycle by providing the mitochondrion with ADP that acts as an acceptor for phosphoryl groups. Furthermore, this acceleration of the TCA cycle stimulates protein synthesis via two mechanisms: first, by increasing ATP production, and second, by provision of certain amino acids required for protein synthesis, since the amino acids glutamate, alanine, and aspartate are either reduction products or partially oxidized products of the intermediates of glycolysis and the TCA cycle. The utilization of oxygen in the course of the TCA cycle turnover is relatively diminished even though TCA cycle intermediates are being consumed. With partial oxidation of TCA cycle intermediates into amino acids, there is necessarily a reduction in formation of CO₂ from pyruvate, seen as a relative diminution in utilization of oxygen in relation to carbon utilization. This has been assumed to be an inhibition of oxygen uptake and therefore a diminution of TCA cycle activity. Therefore a switch from oxidative metabolism to glycolytic metabolism has been assumed (the Crabtree effect). By stimulating both ATP production and protein synthesis for the rapidly dividing cell, the binding of hexokinase to mitochondrial porin lies at the core of proliferative energy metabolism. This article further reviews literature on the binding of the isozymes of hexokinase to porin, and on the evolution of insulin, proposing that intracellular insulin-like proteins directly bind hexokinase to mitochondrial porin.     

Cerebrospinal Fluid from Sporadic Amyotrophic Lateral Sclerosis Patients Induces Mitochondrial and Lysosomal Dysfunction

In our laboratory, we have developed (1) an in vitro model of sporadic Amyotrophic Lateral Sclerosis (sALS) involving exposure of motor neurons to cerebrospinal fluid (CSF) from sALS patients and (2) an in vivo model involving intrathecal injection of sALS-CSF into rat pups. In the current study, we observed that spinal cord extract from the in vivo sALS model displayed elevated reactive oxygen species (ROS) and mitochondrial dysfunction. Quantitative proteomic analysis of sub-cellular fractions from spinal cord of the in vivo sALS model revealed down-regulation of 35 mitochondrial proteins and 4 lysosomal proteins. Many of the down-regulated mitochondrial proteins contribute to alterations in respiratory chain complexes and organellar morphology. Down-regulated lysosomal proteins Hexosaminidase, Sialidase and Aryl sulfatase also displayed lowered enzyme activity, thus validating the mass spectrometry data. Proteomic analysis and validation by western blot indicated that sALS-CSF induced the over-expression of the pro-apoptotic mitochondrial protein BNIP3L. In the in vitro model, sALS-CSF induced neurotoxicity and elevated ROS, while it lowered the mitochondrial membrane potential in rat spinal cord mitochondria in the in vivo model. Ultra structural alterations were evident in mitochondria of cultured motor neurons exposed to ALS-CSF. These observations indicate the first line evidence that sALS-CSF mediated mitochondrial and lysosomal defects collectively contribute to the pathogenesis underlying sALS.     

A novel membrane anchor for FtsZ is linked to cell wall hydrolysis in Caulobacter crescentus

In most bacteria, the tubulin‐like GTPase FtsZ forms an annulus at midcell (the Z‐ring) which recruits the division machinery and regulates cell wall remodeling. Although both activities require membrane attachment of FtsZ, few membrane anchors have been characterized. FtsA is considered to be the primary membrane tether for FtsZ in bacteria, however in Caulobacter crescentus, FtsA arrives at midcell after stable Z‐ring assembly and early FtsZ‐directed cell wall synthesis. We hypothesized that additional proteins tether FtsZ to the membrane and demonstrate that in C. crescentus, FzlC is one such membrane anchor. FzlC associates with membranes directly in vivo and in vitro and recruits FtsZ to membranes in vitro. As for most known membrane anchors, the C‐terminal peptide of FtsZ is required for its recruitment to membranes by FzlC in vitro and midcell recruitment of FzlC in cells. In vivo, overproduction of FzlC causes cytokinesis defects whereas deletion of fzlC causes synthetic defects with dipM, ftsE and amiC mutants, implicating FzlC in cell wall hydrolysis. Our characterization of FzlC as a novel membrane anchor for FtsZ expands our understanding of FtsZ regulators and establishes a role for membrane‐anchored FtsZ in the regulation of cell wall hydrolysis.     

Toxicity of Artemisia annua (Asteraceae) essential oil on the tea mealy bug,Pseudococcus viburni Sigornet (Hemiptera: Pseudococcidae)

A combination of bioassay and biochemical approaches were used to determine toxicity of Artemisia annua essential oil (AaEO) Pseudococcus viburni. AaEO via leaf dipping bioassay showed LC₅₀ values of 0.693 and 0.419% after two time exposures. Different concentrations of AaEO caused deterrence index between 28.58 to 86.26% by the calculated ED₅₀ of 0.4%. Although, α-esterase activity using α-naphtyl acetate increased in the treated nymphs by AaEO after 24 hours but it showed the lower activity in the treated nymphs using β-naphtyl acetate. Glutathione S-transferase assayed by CDNB showed the higher activity in the treated nymphs than control after 24 hours while the adverse results gained not only after 48 hours but also after 24 hours by using DCNB. No significant differences were found in the activity of alanine aminotransferase versus control, but aspartate aminotransferase and γ-glutamyl transferase showed the statistically higher activities in the treated nymphs in comparison with control. Activities of aldolase and lactate dehydrogenase were significantly lower than those of control. Only acid phosphatase showed the significantly altered activity in the treated nymphs in comparison with control after 24 hours. Results of our study indicated significant toxicity, deterrence and physiological effects of AaEO on P. viburni.     

A novel homogeneous bioluminescence resonance energy transfer element for biomolecular detection with CCD camera or CMOS device

A novel optical signal element based on homogeneous bioluminescence resonance energy transfer (BRET) was developed for biomolecular detection. A fluorescent dye and alkaline phosphatase (AP) conjugate was used as a reporter and light‐generation element for imaging detection platforms that use a CCD camera or CMOS chip‐based devices. In the presence of a luminescence substrate, the energy from the first light emission of a bioluminescence enzymatic reaction was transferred to fluorescent dyes which were conjugated to an enzyme. This resulted in a second light emission with a shorter wavelength. The second light was localized at the position of target molecules without the diffusion problems present in current technology. To optimize energy transfer efficiency, the ratio of enzyme to fluorophore in the conjugates, the fluorescent dyes used in the conjugates and the luminescence substrates used for BRET were investigated. BRET was demonstrated by using both a CCD camera and a CMOS imaging device. Image spatial resolution was greatly improved compared with conventional chemiluminescence detection. This new signal element opens a door for the direct measurement of fluorescent signals on an imaging chip without an external light source and portable instrumentation normally required for the fluorescent detection of biomolecules. Copyright © 2007 John Wiley & Sons, Ltd.     

A Rat Brain Bicistronic Gene with an Internal Ribosome Entry Site Codes for a Phencyclidine-binding Protein with Cytotoxic Activity

The cloning and characterization of the gene for the fourth subunit of a glutamate-binding protein complex in rat brain synaptic membranes are described. The cloned rat brain cDNA contained two open reading frames (ORFs) encoding 8.9- (PRO1) and 9.5-kDa (PRO2) proteins. The cDNA sequence matched contiguous genomic DNA sequences in rat chromosome 17. Both ORFs were expressed within the structure of a single brain mRNA and antibodies against unique sequences in PRO1- and PRO2-labeled brain neurons in situ, indicative of bicistronic gene expression. Dicistronic vectors in which ORF1 and ORF2 were substituted by either two different fluorescent proteins or two luciferases indicated concurrent, yet independent translation of the two ORFs. Transfection with noncapped mRNA led to cap-independent translation of only ORF2 through an internal ribosome entry sequence preceding ORF2. In vitro or cell expression of the cloned cDNA led to the formation of multimeric protein complexes containing both PRO1 and PRO2. These complexes had low affinity (+)-5-methyl-10,11-dihydro-5H-dibenzo[a,d]cyclohepten-5,10-imine (MK-801)-sensitive phencyclidine-binding sites. Overexpression of PRO1 and PRO2 in CHO cells, but not neuroblastoma cells, caused cell death within 24–48 h. The cytotoxicity was blocked by concurrent treatment with MK-801 or by two tetrahydroisoquinolines that bind to phencyclidine sites in neuronal membranes. Co-expression of two of the other subunits of the protein complex together with PRO1/PRO2 abrogated the cytotoxic effect without altering PRO1/PRO2 protein levels. Thus, this rare mammalian bicistronic gene coded for two tightly interacting brain proteins forming a low affinity phencyclidine-binding entity in a synaptic membrane complex.A complex of four proteins purified from brain synaptic membranes was shown to have recognition sites for l-glutamate, N-methyl-d-aspartate (NMDA),⁴ and other ligands characteristic of NMDA receptors in brain, including binding sites for the co-agonist glycine, the modulator spermine, the competitive antagonist (+)-3-(2-carboxypiperazin-4-yl)-propyl-1-phosphonic acid (CPP), and the ion channel inhibitors thienylcyclohexylpiperidine (TCP) and (+)-5-methyl-10,11-dihydro-5H-dibenzo[a,d]cyclohepten-5,10-imine (MK-801) (1, 2). Reconstitution of the purified complex into planar lipid bilayer membranes leads to the formation of channels with four ion conductance levels upon activation by glutamate or NMDA in the presence of glycine (3). These conductances differ from either the predominant NMDA-activated receptor-ion channels of brain neurons or those formed by reconstitution of the NMDA receptor subunits (4), but are similar to those described for ion channels in rat spinal cord motor neurons (5).The genes for three of the proteins in this complex have been cloned and expressed in heterologous cells (6–10). The gene GRINA for the glutamate-binding protein (GBP) subunit was identified as part of a “learning and memory” module of genes expressed in the entorhinal cortex of the mammalian brain (11), and as the gene responsible for mental retardation and epilepsy in infants with a gene duplication in chromosome 8q24.3 (12). Expression of GRINA in heterologous cells leads to activation of mitogen-activated protein kinases (13), i.e. it may be involved in signal transduction in neurons. Because of the potential role of GBP and of the associated membrane complex in cell signaling, there is a need to fully characterize all components of the complex and reconstitute the intact complex in cells lacking in its expression. The genes for two other components of the complex have been cloned, those for the glycine-binding and CPP-binding proteins. But the gene for the fourth subunit has not yet been cloned.The fourth protein of the complex was identified on SDS-PAGE as an ∼40-kDa protein. To complete the characterization of this complex of proteins, the cDNA for the fourth subunit was cloned, and a corresponding genomic sequence in rat genome was identified. The presence of two open reading frames (ORFs) in the cloned cDNA, the expression of both ORFs in a single mRNA in brain, and the translation in brain of the two proteins coded by the cDNA, led to the investigation of the mechanism of translation of both ORFs. Translation of both ORFs through an internal ribosome entry sequence (IRES) was identified, as was the need for the co-expression of the two proteins to create a functional protein, a phencyclidine-binding protein.