The division protein FtsZ interacts with the small heat shock protein IbpA in Acholeplasma laidlawii.

Small heat shock proteins (sHSPs) control the proteins stability in the cell preventing their irreversible denaturation. While many mycoplasmas possess the sHSP gene in the genome, Acholeplasma laidlawii is the only mycoplasma capable of surviving in the environment. Here we report that the sHSP IbpA directly interacts with the key division protein FtsZ in A. laidlawii, representing the first example of such interaction in prokaryotes. FtsZ co-immunoprecipitates with IbpA from A. laidlawii crude extract and in vitro binds IbpA with KD ~ 1 µM. Proteins co-localize in the soluble fraction of the cell at 30-37 °C and in the non-soluble fraction after 1 h exposition to cold stress (4 °C). Under heat shock conditions (42 °C) the amount of FtsZ decreases and the protein remains in both soluble and non-soluble fractions. Furthermore, in vitro, FtsZ co-elutes with IbpAHis6 from A. laidlawii crude extract at any temperatures from 4 to 42 °C, with highest yield at 42 °C. Moreover, in vitro FtsZ retains its GTPase activity in presence of IbpA, and the filaments and bundles formation seems to be even improved by sHSP at 30-37 °C. At extreme temperatures, either 4 or 42 °C, IbpA facilitates FtsZ polymerization, although filaments under 4 °C appears shorter and with lower density, while at 42 °C IbpA sticks around the bundles, preventing their destruction by heat. Taken together, these data suggest that sHSP IbpA in A. laidlawii contributes to the FtsZ stability control and may be assisting appropriate cell division under unfavorable conditions.

LOSP: A putative marker of parasperm lineage in male reproductive system of the prosobranch mollusk Littorina obtusata.

Reproductive isolation is the key attribute of biological species and establishment of the reproductive barriers is an essential event for speciation. Among the mechanisms of reproductive isolation, gamete incompatibility due to the variability of gamete interaction proteins may drive fast divergence even in sympatry. However, the number of available models to study this phenomenon is limited. In case of internally fertilized invertebrates, models to study gamete incompatibility and sperm competition mechanisms are restricted to a single taxon: insects. Here, we propose a group of closely related Littorina species as a new model for such studies. Particularly since periwinkles are already thoroughly studied in terms of morphology, physiology, ecology, phylogeny, and ecological speciation. Earlier, we have identified the first species-specific Littorina sperm protein (LOSP) with no known conservative domains or homologies. LOSP is relatively abundant component of sperm extracts and might be involved in gamete incompatibility. Here, we characterize its definitive localization and mRNA expression pattern in the male reproductive system by immunocytochemistry and RNA in situ hybridization. We demonstrate that LOSP distribution is limited to the parasperm cells. Losp gene expression occurs only at the early stages of parasperm development. The protein is stored within granules of mature parasperm and, most likely, is released after ejaculation inside female reproductive system. Thus, LOSP is the only described molluscan paraspermal protein to date, and there is a possibility for LOSP to be involved in gamete incompatibility since heterospermy is a common phenomenon among Littorina.

On reprogramming of tumor cells metabolism: detection of glycogen in the cell lines of hepatocellular origin with various degrees of dedifferentiation.

The reprogramming of cancer cells includes shifts in glucose and glycogen metabolism. The aim of our work was to check the ability of forming glycogen grains in hepatocellular tumor cell lines of various dedifferentiation levels. We studied the monolayer culture established in vitro after explanting cells from rat ascites Zajdela hepatoma strain C (ZH-C) as a "parental" line and its five daughter clonal sublines: the holoclonal sublines 3H, 5F, 6H and the meroclonal ones 1E, 9C, which possess, respectively, the properties of cancer stem-like cells (CSLCs) and cancer progenitor-like cells (CPLCs). Besides, we studied four permanent cell lines of a rat hepatoma HTC, two murine hepatomas BWTG3 and MH-22a, and human hepatoblastoma HepG2. We used normal rat hepatocytes as positive control cells that form glycogen. We estimated relative cell dedifferentiation levels of the studied lines via analysis of cell morphology, morphometry and motility character on stained cell preparations and lifetime video files. Glycogen in the cells was detected using a Schiff type Au-SO2 reagent. All studied hepatocellular tumor lines were not of equal dedifferentiation level as manifested by different nucleus-to-cytoplasm ratio, by epithelium-like or fibroblast-like morphology, by tight or loosen intercellular contacts, by cell migration of collective or individual types. Glycogen fluorescence of uneven intensity was observed in all normal rat hepatocytes, but only in some cell groups or in single cells of hepatocellular tumor lines. The large or small fluorescent grains were found not only in relatively less dedifferentiated parental ZH-C line, BWTG3 and HepG2 lines, but also in moderately dedifferentiated 1E and HTC lines and even in severely dedifferentiated 3H, 5F and 6H sublines, as well as in the islets of the rat ascites hepatoma induced in vivo by the injection of 3H cells (the tumor-initiating cells). On the other hand, MH-22 and 9C lines, being relatively less and moderately dedifferentiated, showed no glycogen fluorescence. Thus, in 10 tumor cell lines of hepatocellular origin, an ability to reserve glycogen manifested no obvious dependency on their dedifferentiation level. Glycogen grains were detected in some cells even of the severely dedifferentiated lines: in single CSLCs of holoclonal ZH sublines grown in vitro and in a majority of tumor-initiating cells derived from ascites hepatoma in vivo. We suggest that dynamic changes in glycogen formation in CSLCs and tumor-initiating cells might be of importance for their dedifferentiation, self-renewal in vitro, survival and metastasis in vivo. The role of glycogen in maintaining viability and metastasis of tumor cells is to be further studied.

Apnea induction for invasive lung function testing in infant olive baboons: Comparison of intravenous propofol versus hyperventilation.

BACKGROUND: In various types of pulmonary research, pulmonary function testing (PFT) is performed to quantify the severity of lung disease. Induction of apnea and positive pressure ventilation are required for accurate PFT measurements in non-cooperative subjects. We compared two methods of apnea induction in infant olive baboons (Papio anubis). METHODS: Pulmonary function testing results were compared during apnea induced by hyperventilation (CO2 washout) vs. intravenous propofol (1 dose 10 mg/kg). PFT was evaluated using a hot-wire pneumotachometer incorporated within an Avea ventilator in nine 1-month-old baboons. RESULTS: Propofol induced apnea faster and more reliably. In both groups, PFT values passed the statistical equivalence test and were not significantly different (Student's t-test). There was a trend toward less data variability after propofol administration. CONCLUSIONS: Intravenous propofol was non-inferior to CO2 washout for apnea induction in infant olive baboons. Propofol induced apnea faster and more reliably and yielded less variable PFT results.

Reduction of Endotracheal Tube Connector Dead Space Improves Ventilation: A Bench Test on a Model Lung Simulating an Extremely Low Birth Weight Neonate.

BACKGROUND: The reduction of instrumental dead space is a recognized approach to preventing ventilation-induced lung injury in premature infants. However, there are no published data regarding the effectiveness of instrumental dead-space reduction in endotracheal tube (ETT) connectors. We tested the impact of the Y-piece/ETT connector pairs with reduced instrumental dead space on CO2 elimination in a model of the premature neonate lung. METHODS: The standard ETT connector was compared with a low-dead-space ETT connector and with a standard connector equipped with an insert. We compared the setups by measuring the CO2 elimination rate in an artificial lung ventilated via the connectors. The lung was connected to a ventilator via a standard circuit, a 2.5-mm ETT, and one of the connectors under investigation. The ventilator was run in volume-controlled continuous mandatory ventilation mode. RESULTS: The low-dead-space ETT connector/Y-piece and insert-equipped standard connector/Y-piece pairs had instrumental dead space reduced by 36 and 67%, respectively. With set tidal volumes (VT) of 2.5, 5, and 10 mL, in comparison with the standard ETT connector, the low-dead-space connector reduced CO2 elimination time by 4.5% (P < .05), 4.4% (P < .01), and 7.1% (not significant), respectively. The insert-equipped standard connector reduced CO2 elimination time by 13.5, 25.1, and 16.1% (all P < .01). The low-dead-space connector increased inspiratory resistance by 17.8% (P < .01), 9.6% (P < .05), and 5.0% (not significant); the insert-equipped standard connector increased inspiratory resistance by 9.1, 8.4, and 5.9% (all not significant). The low-dead-space connector decreased expiratory resistance by 6.8% (P < .01) and 1.8% (not significant) and increased it by 1.4% (not significant); the insert-equipped standard connector decreased expiratory resistance by 1.5 and 1% and increased it by 1% (all not significant). The low-dead-space connector increased work of breathing by 4.7% (P < .01), 3.8% (P < .01), and 2.5% (not significant); the insert-equipped standard connector increased it by 0.8% (not significant), 2.5% (P < .01), and 2.8% (P < .01). CONCLUSIONS: Both methods of instrumental dead-space reduction led to improvements in artificial lung ventilation. Negative effects on resistance and work of breathing appeared minimal. Further testing in vivo should be performed to confirm the lung model results and, if successful, translated into clinical practice.

Polyclonal antibodies against human proteasome subunits PSMA3, PSMA5, and PSMB5.

A proteasome is a multi-subunit protein complex, which plays a central role in ubiquitin-dependent protein degradation in all eukaryotic cells. The 26S proteasome is composed of a catalytic 20S core complex and one or two 19S regulatory complexes. The 20S core complex forms a cylinder consisting of four stacked rings of seven α (PSMA1-7) or ß (PSMB1-7) subunits. Target proteins are degraded in the cavity of the 20S complex due to proteolytic activities of three ß subunits having catalytic sites located on the inner surface of the cylinder. The aim of this study was the generation of polyclonal antibodies against human proteasome subunits PSMA3, PSMA5, and PSMB5 and characterization of their experimental applications. To construct GST-fusion proteins, DNA sequences encoding PSMA3, PSMA5, and PSMB5 were cloned into prokaryotic expression vectors pGEX-5X-1 or pGEX-4T-3. Recombinant proteins GST-PSMA3, GST-PSMA5, and GST-PSMB5 were highly expressed in E. coli BL21 (DE3) cells, purified by glutathione-affinity chromatography and further used for rabbit immunization. The activity and specificity of the obtained antibody-containing sera were evaluated using Western blot analysis and immunoprecipitation. We have shown by Western blot analysis that our anti-PSMA3, anti-PSMA5, and anti-PSMB5 antibodies recognized both recombinant and endogenous proteins from different human cell lines. We have also shown that anti-PSMA3 and anti-PSMA5 sera were able to recognize and immunoprecipitate native forms of both endogenous and overexpressed FLAG-tagged proteins PSMA3 and PSMA5, respectively. Thus, the antibodies generated against PSMA3, PSMA5, and PSMB5 can be used in various experimental applications, including the evaluation of cellular levels of proteasome subunits in cell extracts and affinity purification of the endogenous and/or overexpressed proteasome subunits, which facilitates subsequent analysis of their post-translational modifications as well as protein-protein interactions in vivo.

The identification and characterization of IbpA, a novel α-crystallin-type heat shock protein from mycoplasma.

α-Crystallin-type small heat shock proteins (sHsps) are expressed in many bacteria, animals, plants, and archaea. Among mycoplasmas (Mollicutes), predicted sHsp homologues so far were found only in the Acholeplasmataceae family. In this report, we describe the cloning and functional characterization of a novel sHsp orthologue, IbpA protein, present in Acholeplasma laidlawii. Importantly, similar to the endogenously expressed sHsp proteins, the recombinant IbpA protein was able to spontaneously generate oligomers in vitro and to rescue chemically denatured bovine insulin from irreversible denaturation and aggregation. Collectively, these data suggest that IbpA is a bona fide member of the sHsps family. The immune-electron microscopy data using specific antibodies against IbpA have revealed different intracellular localization of this protein in A. laidlawii cells upon heat shock, which suggests that IbpA not only may participate in the stabilization of individual polypeptides, but may also play a protective role in the maintenance of various cellular structures upon temperature stress.

A new look at the pathogenesis of the meconium aspiration syndrome: a role for fetal pancreatic proteolytic enzymes in epithelial cell detachment.

We hypothesized that fetal pancreatic digestive enzymes play a role in the lung damage after meconium aspiration. We studied the effect of meconium on the A549 alveolar epithelial cell line. The exposure of the cells to 0.5 to 5% meconium resulted in significant disruption of connections between A549 cells and caused dose-dependent cell detachment, without signs of cell death. A protease inhibitor cocktail prevented the A549 cell detachment induced by meconium. After the exposure to 2.5% meconium, a protective effect was quantified by measuring light absorbance by gentian violet stain of still attached cells. The protease inhibitor cocktail and chymostatin showed significant protective effects, increasing the number of attached cells by 135 and 123%, respectively (p < 0.05). Other individual protease inhibitors tested in the detachment assay (AEBSF, leupeptin, E-64, aprotinin, benzamidine, phosphamidon, and aminohexanoic acid) did not offer statistically significant protection. These results afford a new perspective on the pathophysiology of meconium aspiration syndrome (MAS). We speculate that disruption of intercellular connections and cell detachment from the basement membrane are key events in the pathology associated with MAS. The observed protective effects of protease inhibitors suggest that they may be useful in the treatment and/or prophylaxis of MAS.

Atrial granular cells of the snail Achatina fulica release proteins into hemolymph after stimulation of the heart nerve.

The atrium of the gastropod mollusc Achatina fulica receives rich innervation and contains numerous granular cells (GCs). We studied the atrial innervation and discovered that axon profiles typical in appearance of peptidergic neurons form close unspecialized membrane contacts with GCs. Then, we investigated, at both morphological and biochemical levels, the effect of electrical stimulation of the heart nerve on GCs of Achatina heart perfused in situ. The ultrastructural study demonstrated changes in granule morphology consistent with secretion. These events included alteration of granule content, intracellular granule fusion and formation of complex degranulation channels, within which the granule matrix solubilized. It was shown that electrical stimulation resulted in a significant increase of the total protein concentration in the perfusate. Furthermore, SDS-PAGE analysis of the perfusate revealed three new proteins with molecular masses of 16, 22, and 57 kDa. Affinity-purified polyclonal antibodies against the 16 kDa protein were obtained; the whole-mount immunofluorescence technique revealed the presence of this protein in the granules of atrial GCs. In GCs of the stimulated atrium, a progressive loss of their granular content was observed. The results suggest that the central nervous system can modulate the secretory activity of the atrial GCs through non-synaptic pathways.

Meconium aspiration syndrome treatment - new approaches using old drugs.

Presently, modern medicine does not offer any disease-modifying treatment for meconium aspiration syndrome (MAS). Several medications with already established safety profiles when employed for similar or other conditions could be useful for MAS treatment. N-Acetylcysteine and DNAse have the capability to reduce viscosity and thickness of meconium by breaking disulfide bonds and slicing DNA, respectively. N-Acetylcysteine, antiprotease drugs, or low pH buffer solutions may have the capability to neutralize meconium's digestive enzymes responsible for lung damage in patients with MAS. All these compounds have great potential to reduce meconium's pathogenic properties which in turn could alleviate MAS severity.