You can read and write using a single column `DataFrame`

just fine:

```
import pandas.util.testing as tm
from pandas import read_csv
df = tm.makeTimeDataFrame()
dfa = df[['A']].T
dfa.to_csv('the_csv.csv')
dfa_hat = read_csv('the_csv.csv', index_col=0)
dfa_hat.T
```

But I suspect that isn't your problem. You're misunderstanding that when you call `DataFrame.mean()`

you're performing a reduction along an axis (`axis == 0`

by default).

Let's look at a simple example:

```
In [272]: df = DataFrame(randn(5, 2), columns=list('ab'))
In [273]: df
Out[273]:
a b
0 0.056 -0.056
1 -0.384 1.153
2 0.524 -1.545
3 1.082 1.665
4 -0.593 -0.412
In [274]: df.mean()
Out[274]:
a 0.137
b 0.161
dtype: float64
In [275]: type(df.mean())
Out[275]: pandas.core.series.Series
```

Notice that the `index`

of `df.mean()`

is the `columns`

of `df`

. That's because I reduced across the rows. Also notice that `type(df.mean())`

is `Series`

which is the `pandas`

equivalent of numpy array with a single axis, that is, a vector. This is by design. It may *look* like a column when it prints out to the console, but it behaves pretty much identically to `numpy`

arrays with respect to when it is treated as a column versus a row by `numpy`

.

In `pandas`

however, `Series`

objects are always treated like columns except in cases where rows are explicitly requested by the user. For example, the rows of a `DataFrame`

can be accessed as `Series`

objects (though this is often inefficient with heterogeneous columns). This is how `numpy`

works too: individual rows and columns are 1D arrays.

So to answer your question, just like a 1D `numpy`

array returns itself when `T`

is called on it, so will a `Series`

object.