Synthesis of a biotin derivative of iberiotoxin: binding interactions with streptavidin and the BK Ca2+-activated K+ channel expressed in a human cell line

Iberiotoxin (IbTx) is a scorpion venom peptide that inhibits BK Ca2+-activated K+ channels with high affinity and specificity. Automated solid-phase synthesis was used to prepare a biotin-labeled derivative (IbTx-LC-biotin) of IbTx by substitution of Asp19 of the native 37-residue peptide with N--(D-biotin-6-amidocaproate)-L-lysine. Both IbTx-LC-biotin and its complex with streptavidin (StrAv) block single BK channels from rat skeletal muscle with nanomolar affinity, indicating that the biotin-labeled residue, either alone or in complex with StrAv, does not obstruct the toxin binding interaction with the BK channel. IbTx-LC-biotin exhibits high affinity (KD = 26 nM) and a slow dissociation rate (koff = 5.4 x 10(-4) s(-1)) in a macroscopic blocking assay of whole-cell current of the cloned human BK channel. Titration of IbTx-LC-biotin with StrAv monitored by high performance size exclusion chromatography is consistent with a stoichiometry of two binding sites for IbTx-LC-biotin per StrAv tetramer, indicating that steric interference hinders simultaneous binding of two toxin molecules on each of the two biotin-binding faces of StrAv. In combination with fluorescent conjugates of StrAv or anti-biotin antibody, IbTx-LC-biotin was used to image the surface distribution of BK channels on a transfected cell line. Fluorescence microscopy revealed a patch-like surface distribution of BK channel protein. The results support the feasibility of using IbTx-LC-biotin and similar biotin-tagged K+ channel toxins for diverse applications in cellular neurobiology. .     

Mechanisms of emphysema in autosomal dominant cutis laxa

Heterozygous elastin gene mutations cause autosomal dominant cutis laxa associated with emphysema and aortic aneurysms. To investigate the molecular mechanisms leading to cutis laxa in vivo, we generated transgenic mice by pronuclear injection of minigenes encoding normal human tropoelastin (WT) or tropoelastin with a cutis laxa mutation (CL). Three independent founder lines of CL mice showed emphysematous pulmonary airspace enlargement. No consistent dermatological or cardiovascular pathologies were observed. One CL and one WT line were selected for detailed studies. Both mutant and control transgenic animals showed elastin deposition into pulmonary elastic fibers, indicated by increased desmosine levels in the lung and by colocalization of transgenic and endogenous elastin by immunostaining. CL mice showed increased static lung compliance and decreased stiffness of lung tissue. In addition, markers of transforming growth factor-β (TGFβ) signaling and the unfolded protein response (UPR) were elevated together with increased apoptosis in the lungs of CL animals. We conclude that the synthesis of mutant elastin in CL activates multiple downstream disease pathways by triggering a UPR, altered mechanical signaling, increased release of TGFβ and apoptosis. We propose that the combined effects of these processes lead to the development of an emphysematous pulmonary phenotype in CL.     

Incidence of apoptosis in parthenogenetic porcine embryos generated by using protein kinase or protein synthesis inhibitors

In mammals, embryonic development can be artificially initiated by activating the oocyte using a number of methods. In the present research, we investigated whether butyrolactone I and cycloheximide, two chemicals frequently used in combined oocyte activation protocols, have any detrimental effect on programmed cell death in the developing porcine embryo. Parthenogenetic porcine blastocysts were generated by the following methods: (1) electroporation followed by blocking the activity of specific protein kinases with butyrolactone I; (2) electroporation followed by inhibition of protein synthesis using cycloheximide; and (3) electroporation only (control). The viability of the embryos was evaluated by monitoring the frequency of cells with early and late signs of programmed cell death. There was no difference between the embryos in terms of blastocyst formation (ranging from 27.5+/-3.8 and 33.3+/-3.5%) and total nuclear number (ranging from 23.5+/-1.1 and 31.8+/-4.4). In addition, the occurrence of apoptosis was also similar in the three experimental groups. The proportion of cells with active caspase-9 (a sign of early apoptosis) in the blastocysts produced by the different activation methods was between 19.4+/-1.9 and 23.0+/-2.4%. The annexin V assay revealed that phosphatidylserine flip (another early apoptotic event) took place in 24.4+/-2.1 to 32.3+/-2.4% of the blastomeres. Finally DNA fragmentation, a sign of late stage apoptosis determined by the TUNEL assay, occurred in 8.5+/-2.4 to 10.1+/-3.0% of the cells. The results indicate that temporary inhibition of specific protein kinases or protein synthesis does not increase the onset of apoptosis in parthenogenetic porcine blastocysts.     

Activation of retinoic acid receptor signaling coordinates lineage commitment of spontaneously differentiating mouse embryonic stem cells in embryoid bodies

Retinoid signaling has been implicated in embryonic stem cell differentiation. Here we present a systematic analysis of gene expression changes in mouse embryonic stem cells (mESCs), during their spontaneous differentiation into embryoid bodies and the effect of all-trans retinoic acid (ATRA) on this process. We show that retinoic acid is present in the serum and is sufficient to activate retinoid signaling at a basal level in undifferentiated mESCs. This signal disappears during embryoid body formation. However exogenously added ATRA resets the spontaneous differentiation programs in embryoid bodies and initiates a distinct genetic program. These data suggest that retinoid signaling not only promotes a particular pathway but also acts as a context dependent general coordinator of the differentiation states in embryonic stem cells.     

Store-operated calcium entry in human neutrophils reflects multiple contributions from independently regulated pathways

Human polymorphonuclear neutrophil (PMN) responses to G protein-coupled chemoattractants are highly dependent upon store-operated Ca(2+) entry (SOCE). Recent research suggests that SOCE currents can be mediated by a variety of related channel proteins of the transient receptor potential superfamily. SOCE has been regarded as a specific response to depletion of cell calcium stores. We hypothesized that net SOCE might reflect the contributions of more than one calcium entry pathway. SOCE was studied in normal human PMN using Ca(2+) and Sr(2+) ions. We found that PMN SOCE depends on at least two divalent cation influx pathways. One of these was nonspecific and Sr(2+) permeable; the other was Ca(2+) specific. The two pathways show different degrees of dependence on store depletion by thapsigargin and ionomycin, and differential sensitivity to inhibition by 2-aminoethyoxydiphenyl borane and gadolinium. The inflammatory G protein-coupled chemoattractants fMLP, platelet-activating factor, and IL-8 elicit unique patterns of Sr(2+) and Ca(2+) influx channel activation, and SOCE responses to these agonists displayed differing degrees of linkage to prior Ca(2+) store depletion. The mechanisms of PMN SOCE responses to G protein-coupled chemoattractants are physiologically diverse. They appear to reflect Ca(2+) transport through a variety of channels that are independently regulated to varying degrees by store depletion and by G protein-coupled receptor activation.     

Glutamine fuels proliferation but not migration of endothelial cells

Endothelial metabolism is a key regulator of angiogenesis. Glutamine metabolism in endothelial cells (ECs) has been poorly studied. We used genetic modifications and ¹³C tracing approaches to define glutamine metabolism in these cells. Glutamine supplies the majority of carbons in the tricyclic acid (TCA) cycle of ECs and contributes to lipid biosynthesis via reductive carboxylation. EC‐specific deletion in mice of glutaminase, the initial enzyme in glutamine catabolism, markedly blunts angiogenesis. In cell culture, glutamine deprivation or inhibition of glutaminase prevents EC proliferation, but does not prevent cell migration, which relies instead on aerobic glycolysis. Without glutamine catabolism, there is near complete loss of TCA intermediates, with no compensation from glucose‐derived anaplerosis. Mechanistically, addition of exogenous alpha‐ketoglutarate replenishes TCA intermediates and rescues cellular growth, but simultaneously unveils a requirement for Rac1‐dependent macropinocytosis to provide non‐essential amino acids, including asparagine. Together, these data outline the dependence of ECs on glutamine for cataplerotic processes; the need for glutamine as a nitrogen source for generation of biomass; and the distinct roles of glucose and glutamine in EC biology.     

Medicinal applications of fullerenes

Fullerenes have attracted considerable attention in different fields of science since their discovery in 1985. Investigations of physical, chemical and biological properties of fullerenes have yielded promising information. It is inferred that size, hydrophobicity, three-dimensionality and electronic configurations make them an appealing subject in medicinal chemistry. Their unique carbon cage structure coupled with immense scope for derivatization make them a potential therapeutic agent. The study of biological applications has attracted increasing attention despite the low solubility of carbon spheres in physiological media. The fullerene family, and especially C60, has appealing photo, electrochemical and physical properties, which can be exploited in various medical fields. Fullerene is able to fit inside the hydrophobic cavity of HIV proteases, inhibiting the access of substrates to the catalytic site of enzyme. It can be used as radical scavenger and antioxidant. At the same time, if exposed to light, fullerene can produce singlet oxygen in high quantum yields. This action, together with direct electron transfer from excited state of fullerene and DNA bases, can be used to cleave DNA. In addition, fullerenes have been used as a carrier for gene and drug delivery systems. Also they are used for serum protein profiling as MELDI material for biomarker discovery. In this review we report the aspects of medicinal applications of fullerenes.     

Transduction of plant signal molecules by the Rhizobium NodD proteins.

The regulatory NodD proteins of Rhizobium bacteria mediate the activation of a gene set responsible for symbiotic nodule formation by plant signal molecules. Here we discuss the signal recognition and gene activation properties of NodD and present a model summarizing the current knowledge on NodD action.