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Hamster Kidney (hamster + kidney)

Distribution by Scientific Domains
Life Sciences66%

Kinds of Hamster Kidney

  • baby hamster kidney
    		•

    Selected Abstracts

    Adenosine modulates cell growth in baby hamster kidney (BHK) cells

    BIOFACTORS, Issue 4 2000
    Rashmi A. Mittal
    Abstract Adenosine is known to modulate cell growth in a variety of mammalian cells either via the activation of receptors or through metabolism. We investigated the effect of adenosine on Baby Hamster Kidney (BHK) cell growth and attempted to determine its mechanism of modulation. In wild-type BHK cells, adenosine evoked a biphasic response in which a low concentration of adenosine (1± 150;5 ,M) produced an inhibition of colony formation but at higher concentrations (up to 50 ,M) this inhibition was progressively reversed. However, no biphasic response was observed in an ± 147;adenosine kinase± 148; deficient BHK mutant, ± 147;5a± 148;, which suggests that adenosine kinase plays an important role in the modulation of growth response to adenosine. Adenosine receptors did not appear to have a role in regulating cell growth of BHK cells. Specific A1 and A2 receptor antagonists were unable to reverse the effect of adenosine on cell growth. Even though a specific A3 adenosine receptor antagonist MRS-1220 partly reversed the inhibition in colony formation at 1 ,M adenosine, it also affected the transport of adenosine. Thus adenosine transport and metabolism appears to play the major role in this modulation of cell growth as 5,-amino-5,-deoxyadenosine, an adenosine kinase inhibitor, reversed the inhibition of cell growth observed at 1 ,M adenosine. These results, taken together, would suggest that adenosine modulates cell growth in BHK mainly through its transport and metabolism to adenine nucleotides. [source]

    The A-subunit of surface-bound Shiga toxin stimulates clathrin-dependent uptake of the toxin

    FEBS JOURNAL, Issue 16 2005
    Maria L. Torgersen
    Shiga toxin can be internalized by clathrin-dependent endocytosis in different cell lines, although it binds specifically to the glycosphingolipid Gb3. It has been demonstrated previously that the toxin can induce recruitment of the toxin,receptor complex to clathrin-coated pits, but whether this process is concentration-dependent or which part of the toxin molecule is involved in this process, have so far been unresolved issues. In this article, we show that the rate of Shiga toxin uptake is dependent on the toxin concentration in several cell lines [HEp-2, HeLa, Vero and baby hamster kidney (BHK)], and that the increased rate observed at higher concentrations is strictly dependent on the presence of the A-subunit of cell surface-bound toxin. Surface-bound B-subunit has no stimulatory effect. Furthermore, this increase in toxin endocytosis is dependent on functional clathrin, as it did not occur in BHK cells after induction of antisense to clathrin heavy chain, thereby blocking clathrin-dependent endocytosis. By immunofluorescence, we show that there is an increased colocalization between Alexa-labeled Shiga toxin and Cy5-labeled transferrin in HeLa cells upon addition of unlabeled toxin. In conclusion, the data indicate that the Shiga toxin A-subunit of cell surface-bound toxin stimulates clathrin-dependent uptake of the toxin. Possible explanations for this phenomenon are discussed. [source]

    Multiple cleavage sites for polymeric immunoglobulin receptor

    IMMUNOLOGY, Issue 4 2004
    Masatake Asano
    Summary Human polymeric immunoglobulin receptor (pIgR) was expressed in baby hamster kidney (BHK) cells using a recombinant vaccinia virus transfection system. Cleavage of pIgR on the cell surface was partially inhibited by the proteinase inhibitor, leupeptin. We addressed the question whether some particular regions of pIgR could affect the efficient cleavage of this molecule, with the following results: (1) a mutant lacking the entire cytoplasmic region resulted in release of secretory component (SC) into the culture supernatant much faster than wild-type; (2) a pIgR mutant lacking the entire extracellular domain 6, the region containing the susceptible cleavage sites, could be cleaved and released as a mutant SC. The transport kinetics of this mutant between endoplasmic reticulum (ER) and Golgi or Golgi and the cell surface was equivalent to wild-type pIgR. Our results indicate that although the main cleavage site is in domain 6, at least one other cleavage site may exist. [source]

    Adenosine modulates cell growth in baby hamster kidney (BHK) cells

    BIOFACTORS, Issue 4 2000
    Rashmi A. Mittal
    Abstract Adenosine is known to modulate cell growth in a variety of mammalian cells either via the activation of receptors or through metabolism. We investigated the effect of adenosine on Baby Hamster Kidney (BHK) cell growth and attempted to determine its mechanism of modulation. In wild-type BHK cells, adenosine evoked a biphasic response in which a low concentration of adenosine (1± 150;5 ,M) produced an inhibition of colony formation but at higher concentrations (up to 50 ,M) this inhibition was progressively reversed. However, no biphasic response was observed in an ± 147;adenosine kinase± 148; deficient BHK mutant, ± 147;5a± 148;, which suggests that adenosine kinase plays an important role in the modulation of growth response to adenosine. Adenosine receptors did not appear to have a role in regulating cell growth of BHK cells. Specific A1 and A2 receptor antagonists were unable to reverse the effect of adenosine on cell growth. Even though a specific A3 adenosine receptor antagonist MRS-1220 partly reversed the inhibition in colony formation at 1 ,M adenosine, it also affected the transport of adenosine. Thus adenosine transport and metabolism appears to play the major role in this modulation of cell growth as 5,-amino-5,-deoxyadenosine, an adenosine kinase inhibitor, reversed the inhibition of cell growth observed at 1 ,M adenosine. These results, taken together, would suggest that adenosine modulates cell growth in BHK mainly through its transport and metabolism to adenine nucleotides. [source]

    Logistic Equations Effectively Model Mammalian Cell Batch and Fed-Batch Kinetics by Logically Constraining the Fit

    BIOTECHNOLOGY PROGRESS, Issue 4 2005
    Chetan T. Goudar
    A four-parameter logistic equation was used to fit batch and fed-batch time profiles of viable cell density in order to estimate net growth rates from the inoculation through the cell death phase. Reduced three-parameter forms were used for nutrient uptake and metabolite/product formation rate calculations. These logistic equations constrained the fits to expected general concentration trends, either increasing followed by decreasing (four-parameter) or monotonic (three-parameter). The applicability of this approach was first verified for Chinese hamster ovary (CHO) cells cultivated in 15-L batch bioreactors. Cell density, metabolite, and nutrient concentrations were monitored over time and used to estimate the logistic parameters by nonlinear least squares. The logistic models fit the experimental data well, supporting the validity of this approach. Further evidence to this effect was obtained by applying the technique to three previously published batch studies for baby hamster kidney (BHK) and hybridoma cells in bioreactors ranging from 100 mL to 300 L. In 27 of the 30 batch data sets examined, the logistic models provided a statistically superior description of the experimental data than polynomial fitting. Two fed-batch experiments with hybridoma and CHO cells in benchtop bioreactors were also examined, and the logistic fits provided good representations of the experimental data in all 25 data sets. From a computational standpoint, this approach was simpler than classical approaches involving Monod-type kinetics. Since the logistic equations were analytically differentiable, specific rates could be readily estimated. Overall, the advantages of the logistic modeling approach should make it an attractive option for effectively estimating specific rates from batch and fed-batch cultures. [source]

    Cell permeabilization by poliovirus 2B viroporin triggers bystander permeabilization in neighbouring cells through a mechanism involving gap junctions

    CELLULAR MICROBIOLOGY, Issue 8 2010
    Vanesa Madan
    Summary Poliovirus 2B protein is a well-known viroporin implicated in plasma membrane permeabilization to ions and low-molecular-weight compounds during infection. Translation in mammalian cells expressing 2B protein is inhibited by hygromycin B (HB) but remains unaffected in mock cells, which are not permeable to the inhibitor. Here we describe a previously unreported bystander effect in which healthy baby hamster kidney (BHK) cells become sensitive to HB when co-cultured with a low proportion of cells expressing poliovirus 2B. Viroporins E from mouse hepatitis virus, 6K from Sindbis virus and NS4A protein from hepatitis C virus were also able to permeabilize neighbouring cells to different extents. Expression of 2B induced permeabilization of neighbouring cell lines other than BHK. We found that gap junctions are responsible mediating the observed bystander permeabilization. Gap junctional communication was confirmed in 2B-expressing co-cultures by fluorescent dye transfer. Moreover, the presence of connexin 43 was confirmed in both mock and 2B-transfected cells. Finally, inhibition of HB entry to neighbouring cells was observed with 18,-glycyrrhethinic acid, an inhibitor of gap junctions. Taken together, these findings support a mechanism involving gap junctional intercellular communication in the bystander permeabilization effect observed in healthy cells co-cultured with poliovirus 2B-expressing cells. [source]