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 B 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 B1-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. Correspondence to: S. I. Tomarev     

Transcriptional regulation of the gene for prothoracicotropic hormone in the silkworm, <Emphasis Type="Italic">Bombyx mori</Emphasis>

Prothoracicotropic hormone (PTTH) is one of key players in regulation of insect growth, molting, metamorphosis, diapause, and is expressed specifically in the two pairs of lateral PTTH-producing neurosecretory cells in the brain. Analysis of cis-regulatory elements of the PTTH promoter might elucidate the regulatory mechanism controlling PTTH expression. In this study, the PTTH gene promoter of Bombyx mori (Bom-PTTH) was cloned and sequenced. The cis-regulatory elements in Bom-PTTH gene promoter were predicted using Matinspector software, including myocyte-specific enhancer factor 2, pre-B-cell leukemia homeobox 1, TATA box, etc. Transient transfection assays using a series of fragments linked to the luciferase reporter gene indicated that the fragment spanning −110 to +33 bp of the Bom-PTTH promoter showed high ability to support reporter gene expression, but the region of +34 to +192 bp and −512 to −111 bp repressed the promoter activity in the BmN and Bm5 cell lines. Electrophoretic mobility shift assays demonstrated that the nuclear protein could specifically bind to the region spanning −124 to −6 bp of the Bom-PTTH promoter. Furthermore, we observed that the nuclear protein could specifically bind to the −59 to −30 bp region of the Bom-PTTH promoter. A classical TATA box, TATATAA, localized at positions −47 to −41 bp, which is a potential site for interaction with TATA box binding protein (TBP). Mutation of this TATA box resulted in no distinct binding band. Taken together, TATA box was involved in regulation of PTTH gene expression in B. mori.     

Structural and functional analyses of Arabidopsis thaliana chlorophyll a/b-binding protein (cab) promoters

Arabidopsis thaliana carries three functional copies of the chlorophyll a/b-binding protein (cab) gene which code for an identical mature protein. DNA sequence comparison of all three cab promoters indicated that cab2 and cab3 are more closely related compared to cab1. Although the highest degree of homology was found between the TATA box and -256 of cab3 promoter, suggesting that this region plays a major role in promoter function, this promoter regions are only 47% homologous. To study whether these promoters are regulated by identical cis-acting regulatory elements, the promoters were mutated by progressive deletions and the effects on the promoter activity were measured in either transformed plants or cultured cells. It was found that the minimum sequence necessary for the light-dependent tissue-specific promoter activity of the cab3 is the 89 bp DNA fragment (between -74 and -164) at the region of the TATA and the CCAAT boxes. However, an additional 45 bp DNA fragment (between -164 and -209) upstream of the CCAAT box was necessary for the full promoter activity in the leaves. The regulatory element in the 45 bp region appears to be a positive regulator or enhancer which is specific to photosynthetic cells, since the region did not enhance the promoter activity in cultured cells. This region contains an octamer, TGCCACGT (cab2) or TGCCACAT (cab3), which is similar to the previously identified element, TGACACGT from Arabidopsis cab1 promoter. The upstream regions of the cab promoters appear to contain additional elements which are functionally distinct in each promoter since the upstream region of cab1 activated a non-functional nos promoter whereas that of cab3 did not.     

Sequences responsible for the tissue specific promoter activity of a pea legumin gene in tobacco

Summary Maturing pea cotyledons accumulate large quantities of storage proteins at a specific time in seed development. To examine the sequences responsible for this regulated expression, a series of deletion mutants of the legA major seed storage protein gene were made and transferred to tobacco using the Bin19 disarmed Agrobacterium vector system. A promoter sequence of 97 bp including the CAAT and TATA boxes was insufficient for expression. Expression was first detected in a construct with 549 bp of upstream flanking sequence which contained the the leg box element, a 28 bp conserved sequence found in the legumintype genes of several legume species. Constructs containing-833 and-1203 bp of promoter sequence significantly increased levels of expression. All expressing constructs preserved seed specificity and temporal regulation. The results indicate that promoter sequences between positions-97 and-549 bp are responsible for promoter activity, seed specificity, and temporal regulation of the pea legA gene. Sequences between positions-549 and-1203 bp appear to function as enhancer-like elements, to increase expression.