PAX6
Paired box protein Pax-6, also known as aniridia type II protein or oculorhombin, is a protein that in humans is encoded by the PAX6 gene.
Function
PAX6 is a member of the Pax gene family which is responsible for carrying the genetic information that will encode the Pax-6 protein. It acts as a "master control" gene for the development of eyes and other sensory organs, certain neural and epidermal tissues as well as other homologous structures, usually derived from ectodermal tissues. However, it has been recognized that a suite of genes is necessary for eye development, and therefore the term of "master control" gene may be inaccurate. Pax-6 is expressed as a transcription factor when neural ectoderm receives a combination of weak Sonic hedgehog and strong TGF-Beta signaling gradients. Expression is first seen in the forebrain, hindbrain, head ectoderm and spinal cord followed by later expression in midbrain. This transcription factor is most noted for its use in the interspecifically induced expression of ectopic eyes and is of medical importance because heterozygous mutants produce a wide spectrum of ocular defects such as aniridia in humans.Pax6 serves as a regulator in the coordination and pattern formation required for differentiation and proliferation to successfully take place, ensuring that the processes of neurogenesis and oculogenesis are carried out successfully. As a transcription factor, Pax6 acts at the molecular level in the signaling and formation of the central nervous system. The characteristic paired DNA binding domain of Pax6 utilizes two DNA-binding domains, the paired domain, and the paired-type homeodomain. These domains function separately via utilization by Pax6 to carry out molecular signaling that regulates specific functions of Pax6. An example of this lies in HD's regulatory involvement in the formation of the lens and retina throughout oculogenesis contrasted by the molecular mechanisms of control exhibited on the patterns of neurogenesis in brain development by PD. The HD and PD domains act in close coordination, giving Pax6 its multifunctional nature in directing molecular signaling in formation of the CNS. Although many functions of Pax6 are known, the molecular mechanisms of these functions remain largely unresolved. High-throughput studies uncovered many new target genes of the Pax6 transcription factors during lens development. They include the transcriptional activator BCL9, recently identified, together with Pygo2, to be downstream effectors of Pax6 functions.
Role in Human Fetal Development
During human fetal development, PAX6 functions as a master regulatory transcription factor essential for the formation of several organ systems, particularly the eyes, central nervous system, and pancreas. In the developing human eye, PAX6 controls the differentiation and organization of critical structures including the lens, retina, and cornea, and is indispensable for initiating the genetic pathways required for proper ocular formation. Beyond its role in the eye, PAX6 plays a significant part in the patterning of the central nervous system by regulating the proliferation, migration, and specialization of neural progenitor cells during early brain development.A notable aspect of PAX6's function in the human fetus is its involvement in the regionalization of the developing brain. It helps establish gradients of gene expression within the embryonic forebrain, guiding the formation of distinct cortical regions responsible for sensory, motor, and cognitive functions after birth. Although much of this understanding comes from experimental knockout studies in animal models, similar mutations in humans are associated with serious developmental abnormalities, including aniridia and brain malformations, further confirming PAX6's crucial role in human organ development and fetal patterning.
Species distribution
PAX6 protein function is highly conserved across bilaterian species. For instance, mouse PAX6 can trigger eye development in Drosophila melanogaster. Additionally, mouse and human PAX6 have identical amino acid sequences.Genomic organisation of the PAX6 locus varies among species, including the number and distribution of exons, cis-regulatory elements, and transcription start sites, although most elements at the Vertebrata clade do line up with each other. The first work on genomic organisation was performed in quail, but the picture of the mouse locus is the most complete to date. This consists of 3 confirmed promoters, 16 exons, and at least 6 enhancers. The 16 confirmed exons are numbered 0 through 13 with the additions of exon α located between exons 4 and 5, and the alternatively spliced exon 5a. Each promoter is associated with its own proximal exon resulting in transcripts which are alternatively spliced in the 5' un-translated region. By convention, exon for orthologs from other species are named relative to the human/mouse numbering, as long as the organization is reasonably well-conserved.
Of the four Drosophila Pax6 orthologues, it is thought that the eyeless and twin of eyeless gene products share functional homology with the vertebrate canonical Pax6 isoform, while the eyegone and twin of eyegone gene products share functional homology with the vertebrate Pax6 isoform. Eyeless and eyegone were named for their respective mutant phenotypes. These paralogs also play a role in the development in the entire eye-antennal disc, and consequently in head formation. toy positively regulates ey expression.