Expression of the PAX2 gene in human fetal kidney and Wilms' tumor.

We have examined the pattern of expression of the human PAX2 gene in Wilms' tumors and human fetal kidney by Northern blot and in situ hybridization. Human PAX2 encodes a paired box-containing protein and has a high degree of homology with mouse and Drosophila paired box genes. In situ hybridization analysis reveals that PAX2 is expressed in nephrogenic structures in fetal kidney and also in Wilms' tumors. This pattern of expression suggests that PAX2 may have a role in differentiation of tissues in the kidney. In fetal kidney, PAX2 expression rapidly attenuates following the initial differentiation, but no evidence of attenuation was found in Wilms' tumors. The timing of PAX2 expression is restricted to fetal development, although high levels of expression were also observed in nephrogenic rests of residual normal juvenile kidney tissue adjacent to a Wilms' tumor. Nephrogenic rests are the presumptive precursors of Wilms' tumor but are not necessarily neoplastic. The failure of PAX2 expression to attenuate in Wilms' tumors and nephrogenic rests may be associated with events leading to the onset of Wilms' tumor. By somatic cell hybrid mapping, the PAX2 gene was localized to chromosome 10q22.1-q24.3, although this region has not previously been implicated in Wilms' tumor.     

Molecular role of the PAX5-ETV6 oncoprotein in promoting B-cell acute lymphoblastic leukemia

PAX5 is a tumor suppressor in B-ALL, while the role of PAX5 fusion proteins in B-ALL development is largely unknown. Here, we studied the function of PAX5-ETV6 and PAX5-FOXP1 in mice expressing these proteins from the Pax5 locus. Both proteins arrested B-lymphopoiesis at the pro-B to pre-B-cell transition and, contrary to their proposed dominant-negative role, did not interfere with the expression of most regulated Pax5 target genes. Pax5-Etv6, but not Pax5-Foxp1, cooperated with loss of the Cdkna2a/b tumor suppressors in promoting B-ALL development. Regulated Pax5-Etv6 target genes identified in these B-ALLs encode proteins implicated in pre-B-cell receptor (BCR) signaling and migration/adhesion, which could contribute to the proliferation, survival, and tissue infiltration of leukemic B cells. Together with similar observations made in human PAX5-ETV6⁺ B-ALLs, these data identified PAX5-ETV6 as a potent oncoprotein that drives B-cell leukemia development.     

Further delineation of renal-coloboma syndrome in patients with extreme variability of phenotype and identical PAX2 mutations.

Renal-coloboma syndrome is a recently described autosomal dominant syndrome of abnormal optic nerve and renal development. Two families have been reported with renal-coloboma syndrome and mutations of the PAX2 gene. The PAX2 gene, which encodes a DNA-binding protein, is expressed in the developing ear, CNS, eye, and urogenital tract. Ocular and/or renal abnormalities have been consistently noted in the five reports of patients with renal-coloboma syndrome, to date, but PAX2 expression patterns suggest that auditory and CNS abnormalities may be additional features of renal-coloboma syndrome. To determine whether additional clinical features are associated with PAX2 mutations, we have used PCR-SSCP to identify PAX2 gene mutations in patients. We report here four patients with mutations in exon 2, one of whom has severe ocular and renal disease, microcephaly, and retardation, and another who has ocular and renal disease with high-frequency hearing loss. Unexpectedly, extreme variability in clinical presentation was observed between a mother, her son, and an unrelated patient, all of whom had the same PAX2 mutation as previously described in two siblings with renal-coloboma syndrome. These results suggest that a sequence of seven Gs in PAX2 exon 2 may be particularly prone to mutation.     

Modulation of PAX6 homeodomain function by the paired domain

PAX6 is required for proper development of the eye, central nervous system, and nose. PAX6 has two DNA binding domains, a glycine-rich region that links the two DNA binding domains, and a transactivation domain. There is evidence that the different DNA binding domains of PAX6 have different target genes. However, it is not clear if the two DNA binding domains function independently. We have studied the effect of structural changes in the paired domain on the function of PAX6 mediated through its homeodomain. The R26G and I87R mutations have been reported in different human patients with clinically different phenotypes and are in the N- and the C-terminal halves of the paired domain, respectively. Surprisingly, we found that the I87R mutant protein not only lost the transactivation function but also failed to bind DNA by either of its DNA binding domains. In contrast, the R26G mutant protein lost DNA binding through its paired domain but had greater DNA binding and transactivation than wild-type PAX6 on homeodomain binding sites. Like R26G, the 5a isoform showed higher DNA binding than wild-type PAX6. This study demonstrates that the two subdomains of the paired domain influence the function of the homeodomain differentially and also provides an explanation for the difference in phenotypes associated with these mutations.     

PAX3基因及其蛋白的生物信息学分析

目的：对PAX3基因和PAX3蛋白进行生物信息学分析,更多的了解该基因的相关信息,为进一步研究PAX3与神经管畸形的相关性研究提供基础。方法：运用生物信息学方法对PAX3基因的基因结构、单核苷酸多态性位点（SNP）、PAX3基因与其他基因的相互作用网络、PAX3蛋白结构域、蛋白二级结构、蛋白间相互作用网络、以及PAX3蛋白所调控和影响的靶基因进行分析。结果：PAX3基因有9中可变剪切形式,编码区存在14个SNP位点,其中错意突变13个,移码突变1个。PAX3蛋白由479个氨基酸组成,分子量52968Da,PAX3蛋白可能调控和影响151个靶基因的转录和表达,与PAX3基因存在相互作用的基因和与PAX3蛋白存在相互作用的蛋白多数与发育相关。结论：通过对PAX3基因和PAX3蛋白的生物信息学分析获得了其相应的分子生物学特征,为进一步研究提供基础。     

PAUPAR and PAX6 sequentially regulate human embryonic stem cell cortical differentiation

Long noncoding RNAs (lncRNAs) play a wide range of roles in the epigenetic regulation of crucial biological processes, but the functions of lncRNAs in cortical development are poorly understood. Using human embryonic stem cell (hESC)-based 2D neural differentiation approach and 3D cerebral organoid system, we identified that the lncRNA PAUPAR, which is adjacent to PAX6, plays essential roles in cortical differentiation by interacting with PAX6 to regulate the expression of a large number of neural genes. Mechanistic studies showed that PAUPAR confers PAX6 proper binding sites on the target neural genes by directly binding the genomic regions of these genes. Moreover, PAX6 recruits the histone methyltransferase NSD1 through its C-terminal PST enrichment domain, then regulate H3K36 methylation and the expression of target genes. Collectively, our data reveal that the PAUPAR/PAX6/NSD1 complex plays a critical role in the epigenetic regulation of hESC cortical differentiation and highlight the importance of PAUPAR as an intrinsic regulator of cortical differentiation.