Melinda K. Duncan

Chicken homeobox gene prox 1 related to Drosophila prospero is expressed in the developing lens and retina

Prox 1 is the vertebrate homolog of Drosophila prospero, a gene known to be expressed in the lens‐secreting cone cells of fly ommatidia. Chicken Prox 1 cDNAs were isolated from 14 day embryonic chicken lenses, and a complete open reading frame encoding an 83 kDa protein was elucidated. The homeodomains of chicken and mouse Prox 1 are identical at the amino acid level and are 65–67% similar to the homeodomains of Drosophila and C. elegans prospero. The homology between these proteins extends beyond the homeodomain. There is 56% identity between chicken Prox 1 and Drosophila prospero in the C‐terminal region downstream of the homeodomain, whereas there is little similarity upstream of the homeodomain. Prox 1 is expressed most actively in the developing lens and midgut and at lower levels in the developing brain, heart, muscle, and retina. cDNA sequencing has established that there are alternatively spliced forms of the single Prox 1 gene, which probably account for the two abundant RNAs of about 2 and 8 kb and two less abundant RNAs close to 3.5 kb in length in the lens. In the lens fibers, only the shortest mRNA was present, whereas, in the epithelial cells, both short and long mRNAs were detected. By using in situ hybridization, expression of the Prox 1 gene was first detected at stage 14 in the early lens placode and slightly preceded the expression of δ1‐crystallin, the first crystallin gene expressed in the developing chicken lens. At later stages of development, Prox 1 mRNA was observed throughout the lens, but it appeared more abundant around the bow region of the equator than in the anterior epithelium or the fibers. In the retina, expression of the Prox 1 gene was detected mainly in the inner nuclear layer during later stages of histogenesis. The conserved pattern of Prox 1/prospero gene expression in vertebrates and Drosophila suggests that Prox 1, like Pax‐6, may be essential for eye development in different systematic groups.

Eyes absent: A gene family found in several metazoan phyla

Genes related to the Drosophila eyes absent gene were identified in vertebrates (mouse and human), mollusks (squid), and nematodes (C. elegans). Proteins encoded by these genes consist of conserved C-terminal and variable N-terminal domains. In the conserved 271-amino acid C-terminal region, Drosophila and vertebrate proteins are 65-67% identical. A vertebrate homolog of eyes absent, designated Eya2, was mapped to Chromosome (Chr) 2 in the mouse and to Chr 20q13.1 in human. Eya2 shows a dynamic pattern of expression during development. In the mouse, expression of Eya2 was first detected in 8.5-day embryos in the region of head ectoderm fated to become the forebrain. At later stages of development, Eya2 is expressed in the olfactory placode and in a variety of neural crest derivatives. In the eye, expression of Eya2 was first detected after formation of the lens vesicle. At day 17.5, the highest level of Eya2 mRNA was observed in primary lens fibers. Low levels of Eya2 expression was detected in retina, sciera, and cornea. By postnatal day 10, Eya2 was expressed in secondary lens fibers, cornea, and retina. Although Eya2 is expressed relatively late in eye development, it belongs to the growing list of factors that may be essential for eye development across metazoan phyla. Like members of the Pax-6 gene family, eyes absent gene family members were probably first involved in functions not related to vision, with recruitment for visual system formation and function occurring later.

Spatial and temporal activity of the αB-crystallin/small heat shock protein gene promoter in transgenic mice

In order to study the spatial and temporal activity of the mouse αB‐crystallin/small heat shock gene promoter during embryogenesis, we generated mice harboring a transgene consisting of approximately 4 kbp of αB‐crystallin promoter sequence fused to the Escherichia coli lacZ reporter gene. β‐galactosidase activity was first observed in the heart rudiment of 8.5 days post coitum (d.p.c.) embryos. An identical expression pattern was obtained for the endogenous αB‐crystallin gene by whole mount in situ hybridization. At 9.5 d.p.c., β‐galactosidase activity was detected in the lens placode, in the myotome of the somites, in Rathkes pouch (future anterior pituitary), and in some regions of oral ectoderm. We also examined the stress inducibility of the αB‐crystallin promoter in vivo. Injection of sodium arsenite into mice resulted in increased endogenous αB‐crystallin expression in the adrenal gland and possibly the liver. Our results indicate that visualization of β‐galactosidase activity provides an accurate reflection of endogenous αB‐crystallin expression and demonstrate that the complex developmental pattern of mouse αB‐crystallin gene expression is regulated at the transcriptional level. This expression pattern, coupled with the present literature which addresses functions of the protein, suggests a role for the αB‐crystallin/small heat shock protein in intermediate filament turnover and cellular remodeling which occur during normal development and differentiation.

Developmental regulation of the chicken βB1-crystallin promoter in transgenic mice

The cis-elements responsible for the high-level, lens-specific expression of the chicken beta B1-crystallin gene were investigated by generating mice harboring beta B1-crystallin promoter/chloramphenicol acetyl transferase (CAT) transgenes. Deletion of promoter sequences -434/-153 and -152/-127 as well as site-directed mutagenesis of the PL1 (-116/-102) and Pl2 (-90/-76) elements significantly decreased CAT gene expression in the lenses of adult transgenic mice. Transfection studies using multimerized PL1 and PL2 elements fused to the chicken beta-actin basal promoter indicated that PL1 is a general activating element while PL2 is involved in the lens-specificity of the chicken beta B1-crystallin promoter. CAT histochemistry demonstrated that the chicken beta B1-crystallin promoter (-434/+30) was active in both primary and secondary lens fiber cells from 12.5 days post coitum (dpc) until adulthood. Activity of the -152/+30/CAT transgene was relatively low and confined to the primary lens fiber cells of 16.5 dpc mice. Together, these data suggest that the reduced activity of this promoter in the adult lens is due both to this developmentally restricted expression pattern and a reduction in promoter activity. RNA hybridization studies demonstrated that the chicken beta B1-crystallin/CAT (-434/+30) transgene was expressed at similar levels in the same cells as the endogenous mouse beta B1-crystallin gene in 16.5 dpc transgenic mouse embryos. These data show a strict conservation of the lens-specific spatial and temporal regulation of the chicken and mouse beta B1-crystallin genes.

Convergent evolution of crystallin gene regulation in squid and chicken: The AP-1/ARE connection

Previous experiments have shown that the minimal promoters required for function of the squid SL20-1 and SL11 crystallin genes in transfected rabbit lens epithelial cells contain an overlapping AP-1/antioxidant responsive element (ARE) upstream of the TATA box. This region resembles the PL-1 and PL-2 elements of the chicken βB 1-cry stallin promoter which are essential for promoter function in transfected primary chicken lens epithelial cells. Here we demonstrate by site-directed mutagenesis that the AP-1/ARE sequence is essential for activity of the squid SL20-1 and SL11 promoters in transfected embryonic chicken lens cells and fibroblasts. Promoter activity was higher in transfected lens cells than in fibroblasts. Electrophoretic mobility shift and DNase protection experiments demonstrated the formation of numerous complexes between nuclear proteins of the embryonic chicken lens and the AP-1/ARE sequences of the squid SL20-1 and SL11 crystallin promoters. One of these complexes comigrated and cross-competed with that formed with the PL-1 element of the chicken βB1-crystallin promoter. This complex formed with nuclear extracts from the lens, heart, brain, and skeletal muscle of embryonic chickens and was eliminated by competition with a consensus AP-1 sequence. The nonfunctional mutant AP-1/ ARE sequences did not compete for complex formation. These data raise the intriguing possibility that entirely different, nonhomologous crystallin genes of the chicken and squid have convergently evolved a similar cis-acting regulatory element (AP-1/ARE) for high expression in the lens.

The germ cell deficient locus maps to mouse Chromosome 11A2-3

The autosomal recessive mouse mutation, germ cell dificient, gcd, manifests as infertility in both sexes owing to improper migration and/or proliferation of primordial germ cells during embryonic development. Mice harboring this mutation have been hypothesized to be animal models of the human syndromes, premature ovarian failure and Sertoli cell only syndrome. Since the gcd mutation arose from the insertion of over 100 kb of foreign DNA into the chromosome during a transgenic mouse experiment, fluorescent in situ hybridization with the transgene as a probe was used to determine the chromosomal position of the gcd locus. DAPI chromosomal banding in conjunction with double labeling with the α1(I) collagen gene revealed that the gcd locus is situated on mouse Chromosome (Chr) 11A2–3. Two candidate genes, Lif and Oncostatin M, map near the gcd locus; however, Southern blot hybridization analysis revealed no gross rearrangements in these genes in gcd mice. The chromosomal position of the gcd locus will prove valuable in the search for other candidate genes as well as a landmark for positional cloning experiments.