Diagnoses in kidney disease often depend on quantification and presence of specific structures in the tissue. The progress in the field of whole-slide imaging and deep learning has opened up new possibilities for automatic analysis of histopathological slides. An initial step for renal tissue assessment is the differentiation and segmentation of relevant tissue structures in kidney specimens. We propose a method for segmentation of renal tissue using convolutional neural networks. Nine structures found in (pathological) renal tissue are included in the segmentation task: glomeruli, proximal tubuli, distal tubuli, arterioles, capillaries, sclerotic glomeruli, atrophic tubuli, in ammatory infiltrate and fibrotic tissue. Fifteen whole slide images of normal cortex originating from tumor nephrectomies were collected at the Radboud University Medical Center, Nijmegen, The Netherlands. The nine classes were sparsely annotated by a PhD student, experienced in the field of renal histopathology (MH). Experiments were performed with three different network architectures: a fully convolutional network, a multi-scale fully convolutional network and a U-net. We assessed the added benefit of combining the networks into an ensemble. We performed four-fold cross validation and report the average pixel accuracy per annotation for each class. Results show that convolutional neural net- works are able to accurately perform segmentation tasks in renal tissue, with accuracies of 90% for most classes.