Interaction of an Overexpressed gamma-Tubulin with Microtubules In Vivo and In Vitro

gamma-Tubulin is an ubiquitous MTOC (microtubule-organizing center) component essential for the regulation of microtubule functions. A 1.8 kb cDNA coding for gamma-tubulin was isolated from CHO cells. Analysis of nucleotide sequence predicts a protein of 451 amino acids, which is over 97% identical to human and Xenopus gamma-tubulin. When CHO cells were transiently transfected with the gamma-tubulin clone, epitope-tagged full-length, as well as truncated polypeptides (amino acids 1-398 and 1-340), resulted in the formation of cytoplasmic foci of various sizes. Although one of the foci was identified as the centrosome, the rest of the dots were not associated with any other centrosomal components tested so far. The pattern of microtubule organization was not affected by induction of such gamma-tubulin-containing dots in transfected cells. In addition, the cytoplasmic foci were unable to serve as the site for microtubule regrowth in nocodazole-treated cells upon removal of the drug, suggesting that gamma-tubulin-containing foci were not involved in the activity for microtubule formation and organization. Using the monomeric form of Chlamydomonas gamma-tubulin purified from insect Sf9 cells (), interaction between gamma-tubulin and microtubules was further investigated by immunoelectron microscopy. Microtubules incubated with gamma-tubulin monomers in vitro were associated with more gold particles conjugated with gamma-tubulin than in controls where no exogenous gamma-tubulin was added. However, binding of gamma-tubulin to microtubules was not extensive and was easily lost during sample preparation. Although gamma-tubulin was detected at the minus end of microtubules several times more frequently than the plus end, the majority of gold particles were seen along the microtubule length. These results contradict the previous reports (; ), which might be ascribed to the difference in the level of protein expression in transfected cells.     

In Vitro Spermatogenesis in Lepidopteran Larvae: Role of the Testis Sheath

Summary

Premeiotic spermatocysts from testes of Heliothis virescens larvae were cultured in vitro. These eupyrene cysts progressed through meiosis and elongation in a medium containing calf serum in the absence of ecdysteroids. However, they also required the presence of the testis sheaths. The spermatogenesis-promoting effect of testis sheaths was dose dependent and varied with the donor's age. The active material was extractable from the tissue and was heat stable.     

In Vitro Synthesis of Poliovirus Ribonucleic Acid: Role of the Replicative Intermediate

Poliovirus ribonucleic acid (RNA) polymerase crude extracts could be stored frozen in liquid nitrogen without loss of activity or specificity. The major in vitro product of these extracts was viral single-stranded RNA. However, after short periods of incubation with radioactive nucleoside triphosphates, most of the incorporated label was found in replicative intermediate. When excess unlabeled nucleoside triphosphate was added, the label was displaced from the replicative intermediate and accumulated as viral RNA. It is concluded from this experiment that the replicative intermediate is the precursor to viral RNA. In addition, some of the label was chased into double-stranded RNA. The implications of this finding are discussed.     

Molecular Interaction of S-100 Proteins with Microtubule Proteins In Vitro

Several procedures were employed to examine the in vitro interaction between S-100 proteins and microtubule proteins. Binding of S-100 to tau factors was observed under all experimental conditions. S-100 binding to microtubule-associated protein 2 (MAP2) was best detected by exposing nitrocellulose-immobilized MAP2 or MAPs to either 125I-labeled S-100 or biotinylated S-100. S-100 binding to tubulin was detected when the two protein fractions were first incubated with each other followed by exposure to the bifunctional cross-linker disuccinimidylsuberate, and then separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and transfered onto nitrocellulose paper. By this procedure, complex formation between S-100 and tubulin, as well as between S-100 and a relatively low-molecular-weight MAP, was evidenced by immunoblotting using an anti-S-100 antiserum. Alternatively, complex formation between biotinylated S-100 and either tubulin or MAPs was visualized by means of avidin-peroxidase, after SDS-PAGE of the complex mixtures and transfer of the separated proteins onto nitrocellulose. The interaction between S-100 and tubulin was strictly Ca2+ dependent, and resistant to high concentrations of KCl, colchicine, or vinblastine.     

Interaction of Lipophilic Conjugates of Modified siRNAs with Hematopoietic Cells In Vitro and In Vivo

Russian Journal of Bioorganic Chemistry - Delivery of siRNAs to blood cells is one of the most difficult tasks since there are no efficient and nontoxic methods of delivering nucleic acids to these...     

Acylation of Glucagon-Like Peptide-2: Interaction with Lipid Membranes and In Vitro Intestinal Permeability

Background

Acylation of peptide drugs with fatty acid chains has proven beneficial for prolonging systemic circulation as well as increasing enzymatic stability without disrupting biological potency. Acylation has furthermore been shown to increase interactions with the lipid membranes of mammalian cells. The extent to which such interactions hinder or benefit delivery of acylated peptide drugs across cellular barriers such as the intestinal epithelia is currently unknown. The present study investigates the effect of acylating peptide drugs from a drug delivery perspective.

Purpose

We hypothesize that the membrane interaction is an important parameter for intestinal translocation, which may be used to optimize the acylation chain length for intestinal permeation. This work aims to characterize acylated analogues of the intestinotrophic Glucagon-like peptide-2 by systematically increasing acyl chain length, in order to elucidate its influence on membrane interaction and intestinal cell translocation in vitro.

Results

Peptide self-association and binding to both model lipid and cell membranes was found to increase gradually with acyl chain length, whereas translocation across Caco-2 cells depended non-linearly on chain length. Short and medium acyl chains increased translocation compared to the native peptide, but long chain acylation displayed no improvement in translocation. Co-administration of a paracellular absorption enhancer was found to increase translocation irrespective of acyl chain length, whereas a transcellular enhancer displayed increased synergy with the long chain acylation.

Conclusions

These results show that membrane interactions play a prominent role during intestinal translocation of an acylated peptide. Acylation benefits permeation for shorter and medium chains due to increased membrane interactions, however, for longer chains insertion in the membrane becomes dominant and hinders translocation, i.e. the peptides get ‘stuck’ in the cell membrane. Applying a transcellular absorption enhancer increases the dynamics of membrane insertion and detachment by fluidizing the membrane, thus facilitating its effects primarily on membrane associated peptides.     

Quantifying the Rhythm of KaiB-C Interaction for In Vitro Cyanobacterial Circadian Clock

An oscillator consisting of KaiA, KaiB, and KaiC proteins comprises the core of cyanobacterial circadian clock. While one key reaction in this process-KaiC phosphorylation-has been extensively investigated and modeled, other key processes, such as the interactions among Kai proteins, are not understood well. Specifically, different experimental techniques have yielded inconsistent views about Kai A, B, and C interactions. Here, we first propose a mathematical model of cyanobacterial circadian clock that explains the recently observed dynamics of the four phospho-states of KaiC as well as the interactions among the three Kai proteins. Simulations of the model show that the interaction between KaiB and KaiC oscillates with the same period as the phosphorylation of KaiC, but displays a phase delay of ～8 hr relative to the total phosphorylated KaiC. Secondly, this prediction on KaiB-C interaction are evaluated using a novel FRET (Fluorescence Resonance Energy Transfer)-based assay by tagging fluorescent proteins Cerulean and Venus to KaiC and KaiB, respectively, and reconstituting fluorescent protein-labeled in vitro clock. The data show that the KaiB∶KaiC interaction indeed oscillates with ～24 hr periodicity and ～8 hr phase delay relative to KaiC phosphorylation, consistent with model prediction. Moreover, it is noteworthy that our model indicates that the interlinked positive and negative feedback loops are the underlying mechanism for oscillation, with the serine phosphorylated-state (the "S-state") of KaiC being a hub for the feedback loops. Because the kinetics of the KaiB-C interaction faithfully follows that of the S-state, the FRET measurement may provide an important real-time probe in quantitative study of the cyanobacterial circadian clock.     

Neurons-on-a-Chip: In Vitro NeuroTools

Neurons-on-a-Chip technology has been developed to provide diverse in vitro neuro-tools to study neuritogenesis, synaptogensis, axon guidance, and network dynamics. The two core enabling technologies are soft-lithography and microelectrode array technology. Soft lithography technology made it possible to fabricate microstamps and microfluidic channel devices with a simple replica molding method in a biological laboratory and innovatively reduced the turn-around time from assay design to chip fabrication, facilitating various experimental designs. To control nerve cell behaviors at the single cell level via chemical cues, surface biofunctionalization methods and micropatterning techniques were developed. Microelectrode chip technology, which provides a functional readout by measuring the electrophysiological signals from individual neurons, has become a popular platform to investigate neural information processing in networks. Due to these key advances, it is possible to study the relationship between the network structure and functions, and they have opened a new era of neurobiology and will become standard tools in the near future.     

Limited Trypsinolysis of GroES: The Effect on the Interaction with GroEL and Assembly In Vitro

GroES is a heptameric partner of tetradecameric molecular chaperone GroEL, which ensures the correct folding and assembly of numerous cellular proteins both in vitro and in vivo. This work demonstrates the results of a study of structural aspects of GroES that affect its interaction with GroEL and reassembly. The effect of limited trypsinolysis of GroES on these processes has been studied. It has been shown that limited trypsinolysis of GroES is only strongly pronounced outside the complex with GroEL and results in the cleavage of the peptide bond between Lys20 and Ser21. The N-terminal fragment (~2 kDa) is retained in the GroES particle, which maintains its heptaoligomeric structure but loses the ability to interact with GroEL and dissociates upon a change in the pH from 7 to 8. Trypsin-nicked GroES cannot reassemble after urea-induced unfolding, while the urea-induced unfolding of intact GroES is fully reversible. The reported results indicate the important role of the N-terminal part of GroES subunit in the assembly of its heptameric structure and the interaction with GroEL.     

PrP及其缺失突变体与微管蛋白的体外相互作用的初步研究

为了进一步确定PrP蛋白与微管蛋白是否发生分子间相互作用以及PrP蛋白多肽链中与微管蛋白相互作用的区域,我们表达纯化了全长的PrP以及PrP蛋白缺失突变体,提取了兔脑组织中天然微管蛋白。利用pull-down及免疫共沉淀方法检测全长PrP及PrP蛋白缺失突变体与微管蛋白是否发生分子间相互作用。结果显示,全长His-PrP23-231能与微管蛋白发生体外相互作用,并首次证实了PrP与微管蛋白相互作用的区域位于PrP N端第23位至91位氨基酸。此研究为进一步研究PrP在神经细胞的主动转运机制以及Prion疾病的发病机制提供了一定的理论基础。     

Interaction Between S-100 Proteins and Steady-State and Taxol-Stabilized Microtubules In Vitro

S-100 proteins are a group of three 21-kilodalton, acidic, Ca2+-binding proteins of the "E-F hand" type shown to regulate several cell activities, including microtubule (MT) assembly-disassembly. We show here that S-100 proteins interact with MTs assembled from either whole microtubule protein or purified tubulin, both in the absence and in the presence of the MT-stabilizing drug taxol. Evidence for the binding of S-100 to MTs comes from both kinetic (turbidimetric) and binding studies. Kinetically, S-100 enhances the disassembly of steady-state MTs in the presence of high concentrations of colchicine or vinblastine at 10 microM free Ca2+ and disassembles taxol-stabilized MTs at high Ca2+ concentrations. Experiments performed using 125I-labeled S-100 show that S-100 binds Ca2+ independently to a single set of sites on taxol-stabilized MTs assembled from pure tubulin with an affinity of 6 x 10(-5) M and a stoichiometry of 0.15 mol of S-100/mol of polymerized tubulin. Under certain conditions, S-100 proteins also cosediment with MTs prepared by coassembly of S-100 with MTs, probably in the form of an S-100-tubulin complex. Because S-100 binds to MTs under conditions where this protein fraction does not produce observable effects on the kinetics of assembly-disassembly, e.g., in the absence of Ca2+ at pH 6.7, we conclude that the S-100 binding to MTs does not affect the stability of MTs per se, but rather creates conditions for increased sensitivity of MTs to Ca2+.     

Uptake of Magnesium by Chromaffin Granules In Vitro: Role of the Proton Electrochemical Gradient

Abstract: The chromaffin granule membrane in vitro is impermeable to protons as well as to Mg²⁺; however, when granules are incubated in the presence of the proton ionophore carbonyl cyanide p -trifluoromethoxy-phenylhydrazone or an inhibitor of the granule membrane Mg²⁺-dependent ATPase, the metal ion is accumulated inside the granules. This accumulation is dependent upon the granule transmembrane potential. The simultaneous presence of the ATPase inhibitor and the proton ionophore markedly increases metal ion incorporation. Mg²⁺ incorporation is also promoted by nigericin in the presence of potassium or sodium ions, indicating that Mg²⁺ accumulation is also dependent upon the transmembrane pH gradient. Concomitant with the Mg²⁺ accumulation, there is a significant loss of endogenous catecholamines. It is concluded that Mg²⁺ accumulation is determined by the electrochemical gradient maintained across the membrane. Once the metal ion has accumulated into the granules it displaces catecholamines from their storage sites.     

Tau融合蛋白及其缺失突变体与朊蛋白的体外作用分析

在部分朊病毒病（prion diseases）中,高度磷酸化的微管相关蛋白tau与朊蛋白(prion protein,PrP)发生共定位,tau蛋白可能在朊病毒病的病理机制中有重要作用. 本室已经证明二者可以发生分子间相互作用,本文进一步分析了tau蛋白与prion的体外相互作用及作用位点. 利用RT-PCR方法从人源细胞系SHSY5Y cDNA中扩增出微管相关蛋白tau全长cDNA序列,克隆至质粒pGEX-2T载体,在大肠杆菌中诱导表达融合蛋白GST-tau. 利用GST pull-down及免疫共沉淀方法检测全长tau蛋白与PrP23-231的分子间相互作用. 进一步表达tau 蛋白的各种缺失突变体,确定tau蛋白与PrP蛋白的相互作用位点. 结果表明,所表达的全长tau蛋白及各种缺失突变体均为可溶性蛋白,Western印迹结果显示,各种蛋白均能很好的被tau蛋白单抗识别. GST pull-down和免疫共沉淀实验均显示,原核表达的全长tau蛋白可与全长的PrP蛋白在体外发生相互作用,并确定相互作用位点位于tau蛋白的N端序列及中段的重复区. 上述结果为研究tau蛋白与PrP的相互作用在朊病毒病的发病机制中的意义提供了一定的理论基础.     

Size Effects on the Interaction of QDs with the Mitochondrial Membrane In Vitro

The mitochondrial toxicity induced by GSH-CdTe Quantum dots (QDs) of different sizes was investigated. The decreases in absorbance and transmission electron microscopy images show that QDs induce the swelling of mitochondria. Results of flow cytometry indicate that QDs cause a reduction of mitochondrial membrane potential (MMP). A remarkable increase in fluidity of protein regions of mitochondrial membrane is observed, whereas the lipid regions are not obviously affected. Cyclosporin A (CsA) effectively prevents the QD-induced mitochondrial swelling. On the basis of these results, it is proposed that QDs induce mitochondrial permeability transition (MPT). Moreover, with increasing QDs size, a pronounced MPT is observed. The difference between the membrane fluidity induced by QDs and Cadmium ion and the ineffective protective effects of EDTA suggests that the mitochondrial toxicity of QDs cannot be only attributed to the release of metal ion. The protective effects of HSA indicate that the interaction of QDs with pore-forming protein gives rise to the increase in membrane fluidity. This hypothesis is demonstrated by the interaction of QDs with model membranes and proteins using differential scanning calorimetry and isothermal titration microcalorimetry. In conclusion, as the size of QDs increases, the binding affinity of QDs with membrane protein increases, and therefore causes a pronounced mitochondrial damage.     

Spontaneously Induced Suppressor Cells In Vitro: Nonspecific Suppression of In Vitro Antibody Formation

Nonspecific suppressor cells were induced during in vitro culture of normal mouse spleen cells (SPC) using the Marbrook culture system. The suppressor cells inhibited both the primary and secondary antibody-formation responses antigen nonspecifically in vitro, and both IgM- and IgG-responses were inhibited. The supernatants from suppressive precultured cells were not suppressive. The suppressor cells also inhibited the response of allogeneic SPC beyond H-2 compatibility. The induction of the suppressor cells did not require the presence of antigen but required fetal calf serum (FCS) or both FCS and 2-mercaptoethanol (2-ME). The suppressor cells were generated from the nylon-wool adherent, radiation-sensitive T cell population. On the other hand, the suppressor cells were nylon-wool nonadherent, relatively radiation-sensitive T cells. Actively antibody-producing cells were not affected by the suppressor cells. The suppressor cells inhibited the mitogenic responses of normal SPC to phytohemagglutinin-P (PHA), bacterial lipopolysaccharide (LPS) and concanavalin A (Con A). The suppressor cells themselves inhibited the growth of EL4 cells (T-cell leukemia of C57BL/6 mouse origin) and MOPCll cells (B cells, plasmacytoma of BALB/c mouse origin) even at a low effector-to-target cell ratio (E:T ratio = 1:1), but did not kill these tumor cells. These results indicate that the target cells of the suppressor cells are both T and B cells, and that the mechanism of action of the suppression is either inhibition of proliferation or inhibition of early events in the course of the immune response.     

Cephapirin: In Vitro Antibacterial Spectrum

Cephapirin, a new semisynthetic cephalosporin derivative, was found to have an antibacterial spectrum similar to that of cephalothin. Staphylococcus aureus was inhibited by cephapirin concentrations of 0.09 to 12.5 mug/ml. S. epidermidis, S. viridans, S. pyogenes, and Diplococcus pneumonia isolates were inhibited by less than 1 mug/ml. The Enterococcus required a concentration of 25 mug of antibiotic per ml for inhibition. Approximately 65% of Escherichia coli, and all Klebsiella, indole-negative Proteus, and Salmonella strains tested were inhibited by the drug. Serratia, Pseudomonas, indole-positive Proteus, and Erwinia strains were highly resistant. Inoculum size was not an important factor in determining the level of sensitivity of S. aureus to cephapirin. The antibiotic does not appear to be significantly bound to serum protein. In vitro development of resistance to the drug was demonstrated with two isolates of S. aureus.     

Interaction of Cowpea Mosaic Virus (CPMV) Nanoparticles with Antigen Presenting Cells In Vitro and In Vivo

Background

Plant viruses such as Cowpea mosaic virus (CPMV) are increasingly being developed for applications in nanobiotechnology including vaccine development because of their potential for producing large quantities of antigenic material in plant hosts. In order to improve efficacy of viral nanoparticles in these types of roles, an investigation of the individual cell types that interact with the particles is critical. In particular, it is important to understand the interactions of a potential vaccine with antigen presenting cells (APCs) of the immune system. CPMV was previously shown to interact with vimentin displayed on cell surfaces to mediate cell entry, but the expression of surface vimentin on APCs has not been characterized.

Methodology

The binding and internalization of CPMV by several populations of APCs was investigated both in vitro and in vivo by flow cytometry and fluorescence confocal microscopy. The association of the particles with mouse gastrointestinal epithelium and Peyer''s patches was also examined by confocal microscopy. The expression of surface vimentin on APCs was also measured.

Conclusions

We found that CPMV is bound and internalized by subsets of several populations of APCs both in vitro and in vivo following intravenous, intraperitoneal, and oral administration, and also by cells isolated from the Peyer''s patch following gastrointestinal delivery. Surface vimentin was also expressed on APC populations that could internalize CPMV. These experiments demonstrate that APCs capture CPMV particles in vivo, and that further tuning the interaction with surface vimentin may facilitate increased uptake by APCs and priming of antibody responses. These studies also indicate that CPMV particles likely access the systemic circulation following oral delivery via the Peyer''s patch.