scikit-learn has an implementation of multinomial naive Bayes, which is the right variant of naive Bayes in this situation. A support vector machine (SVM) would probably work better, though.

As Ken pointed out in the comments, NLTK has a nice wrapper for scikit-learn classifiers. Modified from the docs, here's a somewhat complicated one that does TF-IDF weighting, chooses the 1000 best features based on a chi2 statistic, and then passes that into a multinomial naive Bayes classifier. (I bet this is somewhat clumsy, as I'm not super familiar with either NLTK or scikit-learn.)

```
import numpy as np
from nltk.probability import FreqDist
from nltk.classify import SklearnClassifier
from sklearn.feature_extraction.text import TfidfTransformer
from sklearn.feature_selection import SelectKBest, chi2
from sklearn.naive_bayes import MultinomialNB
from sklearn.pipeline import Pipeline
pipeline = Pipeline([('tfidf', TfidfTransformer()),
('chi2', SelectKBest(chi2, k=1000)),
('nb', MultinomialNB())])
classif = SklearnClassifier(pipeline)
from nltk.corpus import movie_reviews
pos = [FreqDist(movie_reviews.words(i)) for i in movie_reviews.fileids('pos')]
neg = [FreqDist(movie_reviews.words(i)) for i in movie_reviews.fileids('neg')]
add_label = lambda lst, lab: [(x, lab) for x in lst]
classif.train(add_label(pos[:100], 'pos') + add_label(neg[:100], 'neg'))
l_pos = np.array(classif.batch_classify(pos[100:]))
l_neg = np.array(classif.batch_classify(neg[100:]))
print "Confusion matrix:\n%d\t%d\n%d\t%d" % (
(l_pos == 'pos').sum(), (l_pos == 'neg').sum(),
(l_neg == 'pos').sum(), (l_neg == 'neg').sum())
```

This printed for me:

```
Confusion matrix:
524 376
202 698
```

Not perfect, but decent, considering it's not a super easy problem and it's only trained on 100/100.