To study the influence of rotating magnetic fields on the expression and intra-nuclear distribution of nucleolin (a protein involved e.g. in ribosome biosynthesis) in two human cell lines.
| Exposure | Parameters |
|---|---|
|
Exposure 1:
35 Hz
Exposure duration:
30 min with an interval of 24 h on 4 days
|
|
|
Exposure 2:
50 Hz
Exposure duration:
30 min with an interval of 24 h on 4 days
|
|
| Frequency | 35 Hz |
|---|---|
| Type | |
| Exposure duration | 30 min with an interval of 24 h on 4 days |
| Additional info | rotating field |
| Measurand | Value | Type | Method | Mass | Remarks |
|---|---|---|---|---|---|
| magnetic flux density | 10 mT | mean | calculated | - | - |
| Frequency | 50 Hz |
|---|---|
| Type | |
| Exposure duration | 30 min with an interval of 24 h on 4 days |
| Additional info | rotating field |
| Exposure source |
|
|---|
| Measurand | Value | Type | Method | Mass | Remarks |
|---|---|---|---|---|---|
| magnetic flux density | 20 mT | mean | calculated | - | - |
In both cell lines repeated short-term exposure to rotating magnetic fields induced significant increase in nucleolin expression in the whole nucleus and in nucleolin aggregates. This effect seemed to be frequency-dependent for K-562 cells while the increase of nucleolin expression in HL-60 cells was higher at the lower frequency. No significant changes in cell cycle phases in both cell lines after exposure were found. This indicates that changes of nucleolin expression induced by rotating magnetic fields are not related to cell cycle.
In conclusion, the nucleolin is responsive to rotating magnetic fields in HL-60 and K-562. The increase of its expression may indicate a reaction of cells to rotating magnetic fields and it may influence other biological properties.
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