Analysis of Band 4.1B in Integrin-Mediated Cell Adhesion and Signaling

Band 4.1B is a cytoskeletal adaptor protein that regulates various cellular behavior; however, the mechanisms by which Band 4.1B contributes to intracellular signaling are unclear. This project addresses in vivo and in vitro functions for Band 4.1B in integrin-mediated cell adhesion and signaling. Band 4.1B has been shown to bind to β8 integrin, although cooperative functions of these two proteins have not been determined. Here, functional links between β8 integrin and Band 4.1B were investigated using gene knockout strategies. Ablation of β8 integrin and Band 4.1B genes resulted in impaired cardiac morphogenesis, leading to embryonic lethality by E11.5. These embryos displayed malformation of the outflow tract that was likely linked to abnormal regulation of cardiac neural crest migration. These data indicate the importance of cooperative signaling between β8 integrin and Band 4.1B in cardiac development. The involvement of Band 4.1B in integrin-mediated cell adhesion and signaling was further demonstrated by studying its functional roles in vitro. Band 4.1B is highly expressed in the brain, but its signaling in astrocytes is not understood. Here, Band 4.1B was shown to promote cell spreading likely by interacting with β1 integrin via its band 4.1, ezrin, radixin, and moesin (FERM) domain in cell adhesions. In astrocytes, both Band 4.1B and β1 integrin were expressed in cell-ECM contact sites during early cell spreading. Exogenous expression of Band 4.1B, especially its FERM domain, enhanced cell spreading on fibronectin, an ECM ligand for β1 integrin. However, the increased cell spreading was prohibited by blocking β1 integrin. These findings suggest that Band 4.1B is crucial for early adhesion assembly and/or signaling that are mediated by β1 integrin. Collectively, this study was the first to establish Band 4.1B as a modulator of integrin-mediated adhesion and signaling.

Positional cloning and characterization of the human aniridia and murine small eye genes

Aniridia (AN) is a congenital, panocular disorder of the eye characterized by the complete or partial absence of the iris. The disease can occur in both the sporadic and familial forms which, in the latter case, is inherited as an autosomal dominant trait with high penetrance. The objective of this study was to isolate and characterize the genes involved in AN and Sey, and thereby to gain a better understanding of the molecular basis of the two disorders.^ Using a positional cloning strategy, I have approached and cloned from the AN locus in human chromosomal band 11p13 a cDNA that is deleted in two patients with AN. The deletions in these patients overlap by about 70 kb and encompass the 3$\sp\prime$ end of the cDNA. This cDNA detects a 2.7 kb mRNA encoded by a transcription unit estimated to span approximately 50 kb of genomic DNA. The message is specifically expressed in all tissues affected in all forms of AN, namely within the presumptive iris, lens, neuroretina, the superficial layers of the cornea, the olfactory bulbs, and the cerebellum. Sequence analysis of the AN cDNA revealed a number of motifs characteristic of certain transcription factors. Chief among these are the presence of the paired domain, the homeodomain, and a carboxy-terminal domain rich in serine, threonine and proline residues. The overall structure shows high homology to the Drosophila segmentation gene paired and members of the murine Pax family of developmental control genes.^ Utilizing a conserved human genomic DNA sequence as probe, I was able to isolate an embryonic murine cDNA which is over 92% homologous in nucleotide sequence and virtually identical at the amino acid level to the human AN cDNA. The expression pattern of the murine gene is the same as that in man, supporting the conclusion that it probably corresponds to the Sey gene. Its specific expression in the neuroectodermal component of the eye, in glioblastomas, but not in the neural crest-derived PC12 pheochromocytoma cell line, suggests that a defect in neuroectodermal rather mesodermal development might be the common etiological factor underlying AN and Sey. ^

HUMAN PROPHASE CHROMOSOME UNIQUE BAND SEQUENCES; DEFINITION, CHARACTERIZATION, AND APPLICATION (CYTOGENETICS, IMAGE PROCESSING)

Extensive experience with the analysis of human prophase chromosomes and studies into the complexity of prophase GTG-banding patterns have suggested that at least some prophase chromosomal segments can be accurately identified and characterized independently of the morphology of the chromosome as a whole. In this dissertation the feasibility of identifying and analyzing specified prophase chromosome segments was thus investigated as an alternative approach to prophase chromosome analysis based on whole chromosome recognition. Through the use of prophase idiograms at the 850-band-stage (FRANCKE, 1981) and a comparison system based on the calculation of cross-correlation coefficients between idiogram profiles, we have demonstrated that it is possible to divide the 24 human prophase idiograms into a set of 94 unique band sequences. Each unique band sequence has a banding pattern that is recognizable and distinct from any other non-homologous chromosome portion.^ Using chromosomes 11p and 16 thru 22 to demonstrate unique band sequence integrity at the chromosome level, we found that prophase chromosome banding pattern variation can be compensated for and that a set of unique band sequences very similar to those at the idiogram level can be identified on actual chromosomes.^ The use of a unique band sequence approach in prophase chromosome analysis is expected to increase efficiency and sensitivity through more effective use of available banding information. The use of a unique band sequence approach to prophase chromosome analysis is discussed both at the routine level by cytogeneticists and at an image processing level with a semi-automated approach to prophase chromosome analysis. ^