Andreas Heuer

The efficient generation of striatal neurons from human embryonic stem cells (hESCs) and induced pluripotent stem cells (hiPSCs) is fundamental for realising their promise in disease modelling, pharmaceutical drug screening and cell therapy for Huntington's disease. GABAergic medium-sized spiny neurons (MSNs) are the principal projection neurons of the striatum and specifically degenerate in the early phase of Huntington's disease. Here we report that activin A induces lateral ganglionic eminence (LGE) characteristics in nascent neural progenitors derived from hESCs and hiPSCs in a sonic hedgehog-independent manner. Correct specification of striatal phenotype was further demonstrated by the induction of the striatal transcription factors CTIP2, GSX2 and FOXP2. Crucially, these human LGE progenitors readily differentiate into postmitotic neurons expressing the striatal projection neuron signature marker DARPP32, both in culture and following transplantation in the adult stria...

In order to provide an animal model of the impulsivity observed in Huntington's disease, the effects of bilateral neostriatal lesions in rats were evaluated in an operant delayed reinforcement task. When given a choice between responding to one lever for a small but immediate reward and a second lever for a larger delayed reward, normal rats exhibit a marked preference for responding to the high reward lever when the imposed delay is short, but progressively choose the lever associated with immediate small reward as the delays increase. Following striatal lesions, the animals continue to express similar preferences, but the lesions initially impose a distinct flattening of the delay-preference function, suggesting a relative insensitivity to the increasing delay parameter in making their response choices. However, this deficit declines with extend retraining on the task, such that 1-2 months after lesion the delay-dependent shift of preference from the delayed to the immediate lever as the delays lengthened was comparable in lesion and sham animals. Amphetamine further disinhibited all animals, apparent as a further increase in the number and reduction of the latencies of responses made to the lever associated with immediate reward. Striatal lesions had little influence on the effects of amphetamine on task performance, other than the increase in the numbers of omissions of lever and panel responses induced by the drug was more marked in the lesion than sham animals, and the lesioned animals exhibited less delay-dependency than the controls in their preference for responding to the lever associated with the larger delayed reinforcement at the highest (1.5 mg/kg) dose tested. The present results indicate small but clear effects of dorsal striatal lesions in an operant delayed reinforcement task, suggestive of an initial impairment in response selection and a reduction in their sensitivity to the delay interval itself. This deficit recovered with further training, which may be dependent upon relearning choice response procedures disrupted by the lesion, but might be reinstated by treatment with stimulant drugs. This article is part of a special issue entitled 'Behavioural, Anatomical, and Genetic Characterisation of Mouse and Rat Models of Huntington's Disease.'

Unilateral dopamine depletion and excitotoxic lesions of the striatum have been shown to induce a contralateral neglect when rats have to respond in a choice reaction time setting. Whereas, in a lateralised setting when response options are to either side of the animal's head all contralateral responding is impaired, testing animals only on one side of the head per day but with a near and far response option, rats are able to correctly respond to contralateral stimuli, but rather bias their responses towards the near hole. Here, we further investigated the nature of the contralateral neglect in egocentric space coding in more detail. Firstly, we tested the effects of near-complete unilateral dopamine depletion on this type of task. Secondly, previous observations suggested that lesioned rats shifted their response strategy which resulted in a response bias towards the most proximal location in contralateral space. In order to "encourage" dopamine depleted rats to respond to the neglected response location we implemented an error correction procedure to the task. Near-complete unilateral dopamine depletion, via 6-hydroxydopamine infusions into the medial forebrain bundle of female Lister Hood rats, resulted in a reduction of usable trials, a near hole bias when animals were tested on the side contralateral to the lesion, as well as increased reaction and movement time latencies. The introduction of an error-correction procedure had no effect on the animals' response bias towards the near contralateral location. Probe trials showed that the bias is most likely the result of responses being misdirected when in a choice situation. The findings further highlight the role of dopamine and an intact striatum to code responses into egocentrically defined space.