Local object gist: meaningful shapes and spatial layout at a very early stage of visual processing

In his introduction, Pinna (2010) quoted one of Wertheimer’s observations: “I stand at the window and see a house, trees, sky. Theoretically I might say there were 327 brightnesses and nuances of color. Do I have ‘327’? No. I have sky, house, and trees.” This seems quite remarkable, for Max Wertheimer, together with Kurt Koffka and Wolfgang Koehler, was a pioneer of Gestalt Theory: perceptual organisation was tackled considering grouping rules of line and edge elements in relation to figure-ground segregation, i.e., a meaningful object (the figure) as perceived against a complex background (the ground). At the lowest level – line and edge elements – Wertheimer (1923) himself formulated grouping principles on the basis of proximity, good continuation, convexity, symmetry and, often forgotten, past experience of the observer. Rubin (1921) formulated rules for figure-ground segregation using surroundedness, size and orientation, but also convexity and symmetry. Almost a century of research into Gestalt later, Pinna and Reeves (2006) introduced the notion of figurality, meant to represent the integrated set of properties of visual objects, from the principles of grouping and figure-ground to the colour and volume of objects with shading. Pinna, in 2010, went one important step further and studied perceptual meaning, i.e., the interpretation of complex figures on the basis of past experience of the observer. Re-establishing a link to Wertheimer’s rule about past experience, he formulated five propositions, three definitions and seven properties on the basis of observations made on graphically manipulated patterns. For example, he introduced the illusion of meaning by comics-like elements suggesting wind, therefore inducing a learned interpretation. His last figure shows a regular array of squares but with irregular positions on the right side. This pile of (ir)regular squares can be interpreted as the result of an earthquake which destroyed part of an apartment block. This is much more intuitive, direct and economic than describing the complexity of the array of squares.

Identification and study of novel genes expressed in the heart precursor cells

Understanding heart development on a molecular level is a requirement for uncovering the causes of congenital heart diseases. Several genes have been implicated as critical for heart development. However, the inducers of these genes as well as their targets and pathways, remain largely unknown. We have identified a promoter element of chick cCer able to drive EGFP expression in a population of cells that consistently exit from the anterior primitive streak region, from as early as stage HH3+, and that later will populate the heart. Using this promoter element as a tool allowed us to identify novel genes previously not known to potentially play a role in heart development. In order to identify and study genes expressed and involved in the correct development and differentiation of the vertebrate heart precursor cell (HPC) lineages, a differential screening using Affymetrix GeneChip® system technologies was performed. Remarkably, this screening led to the identification of more than 700 transcripts differentially expressed in the heart forming regions (HFR). Bioinformatic tools allowed us to filter the large amount of data generated from this approach and to select a few transcripts for in vivo validation. Five genes were selected for further characterization by whole mount in situ hybridization leading to the validation of their expression in the HPC. From those, Adtk1 and Ccbe1 were selected for functional analysis. Regarding to ccbe1, a more detailed WISH analysis was performed and showed that Ccbe1 is expressed specifically on the cardiac progenitors regions at HH4, more specifically in primary heart field and at later stages is present in the second heart field. Further functional analyses by knockdown and overexpression revealed an important role for Ccbe1 in early heart tube formation. Moreover, the results presented in this thesis suggested that Ccbe1 is a key gene during heart development and might be limited to multipotent and highly proliferative progenitors and downregulated upon cellular commitment into more specific cardiac phenotypes. Other of the genes identified, Adtk1 was also subjected to further functional studies. Knockdown of Adtk1 using morpholino oligonucleotides suggested that it might be necessary for the migration and fusion of the heart tube as well as for neural tube closure.