The role of putative human anterior intraparietal sulcus area in observed manipulative action discrimination.

INTRODUCTION: Although it has become widely accepted that the action observation network (AON) includes three levels (occipito-temporal, parietal and premotor), little is known concerning the specific role of these levels within perceptual tasks probing action observation. Recent single cell studies suggest that the parietal level carries the information required to discriminate between two-alternative observed actions, but do not exclude possible contributions from the other two levels. METHODS: Two functional magnetic resonance imaging experiments used a task-based attentional modulation paradigm in which subjects viewed videos of an actor performing a manipulative action on a coloured object, and discriminated between either two observed manipulative actions, two actors or two colours. RESULTS: Both experiments demonstrated that relative to actor and colour discrimination, discrimination between observed manipulative actions involved the putative human anterior intraparietal sulcus (phAIP) area in parietal cortex. In one experiment, where the observed actions also differed with regard to effectors, premotor cortex was also specifically recruited. CONCLUSIONS: Our results highlight the primary role of parietal cortex in discriminating between two-alternative observed manipulative actions, consistent with the view that this level plays a major role in representing the identity of an observed action.

Comparing Parietal Quantity-Processing Mechanisms between Humans and Macaques.

Quantity processing studies typically assume functional homology between regions within macaque and human intraparietal sulcus (IPS), where apparently similar locations respond to broadly similar tasks. However, macaque single cell neurophysiology is difficult to compare to human functional magnetic resonance imaging (fMRI); particularly in multivoxel pattern analysis and adaptation paradigms, or where different tasks are used. fMRI approaches incorporating neural tuning models allow closer comparison, revealing human numerosity-selective responses only outside the IPS. Extensive functional similarities support this novel homology of physical quantity processing. Human IPS instead houses a network responding to comparisons of physical quantities, symbolic numbers, and other stimulus features. This network likely reflects interactions between physical quantity processing, spatial processing, and (in humans) linguistic processing.

The organization of the posterior parietal cortex devoted to upper limb actions: An fMRI study.

The present fMRI study examined whether upper-limb action classes differing in their motor goal are encoded by different PPC sectors. Action observation was used as a proxy for action execution. Subjects viewed actors performing object-related (e.g., grasping), skin-displacing (e.g., rubbing the skin), and interpersonal upper limb actions (e.g., pushing someone). Observation of the three action classes activated a three-level network including occipito-temporal, parietal, and premotor cortex. The parietal region common to observing all three action classes was located dorsally to the left intraparietal sulcus (DIPSM/DIPSA border). Regions specific for observing an action class were obtained by combining the interaction between observing action classes and stimulus types with exclusive masking for observing the other classes, while for regions considered preferentially active for a class the interaction was exclusively masked with the regions common to all observed actions. Left putative human anterior intraparietal was specific for observing manipulative actions, and left parietal operculum including putative human SII region, specific for observing skin-displacing actions. Control experiments demonstrated that this latter activation depended on seeing the skin being moved and not simply on seeing touch. Psychophysiological interactions showed that the two specific parietal regions had similar connectivities. Finally, observing interpersonal actions preferentially activated a dorsal sector of left DIPSA, possibly the homologue of ventral intraparietal coding the impingement of the target person's body into the peripersonal space of the actor. These results support the importance of segregation according to the action class as principle of posterior parietal cortex organization for action observation and by implication for action execution.

K-ras mutations and mucin profile in preneoplastic lesions and colon tumors induced in rats by 1,2-dimethylhydrazine.

K-ras and mucin profile variations, associated with intestinal carcinogenesis, were studied in the preneoplastic lesions, mucin-depleted foci (MDF) and aberrant crypt foci (ACF), and in colonic tumors induced in rats by 1,2-dimethylhydrazine (DMH). The frequency of lesions with K-ras mutations was 23% (3/13), 5.5% (1/18) and 100% (14/14) in MDF, tumors and ACF, respectively. Two of three MDF mutated in K-ras also carried a missense mutation in Apc. We also tested the expression of MUC2, a mucin abundantly expressed in normal colon and M1/MUCA5C, up-regulated in colon carcinogenesis, using immunohistochemistry. MDF and tumors showed a dramatic reduction in the expression of MUC2, whereas ACF showed only a slight reduction. The expression of M1/MUC5AC was almost absent in normal mucosa, but was increased in all the lesions (MDF, tumors and ACF). The expression of the intestinal trefoil factor (ITF), a marker of goblet cell lineage, was reduced in MDF and tumors compared to normal mucosa but not in ACF. In conclusion, although K-ras mutations are present in all ACF, they are less frequent in MDF and tumors; M1/MUC5AC is a marker associated with all preneoplastic events while the reduction of MUC2 and ITF expression is selectively associated with more advanced lesions such as MDF and tumors.