Projection structure of frog rhodopsin in two crystal forms.

Rhodopsin is the G protein-coupled receptor that upon light activation triggers the visual transduction cascade. Rod cell outer segment disc membranes were isolated from dark-adapted frog retinas and were extracted with Tween detergents to obtain two-dimensional rhodopsin crystals for electron crystallography. When Tween 80 was used, tubular structures with a p2 lattice (a = 32 A, b = 83 A, gamma = 91 degrees) were formed. The use of a Tween 80/Tween 20 mixture favored the formation of larger p22(1)2(1) lattices (a = 40 A, b = 146 A, gamma = 90 degrees). Micrographs from frozen hydrated frog rhodopsin crystals were processed, and projection structures to 7-A resolution for the p22(1)2(1) form and to 6-A resolution for the p2 form were calculated. The maps of frog rhodopsin in both crystal forms are very similar to the 9-A map obtained previously for bovine rhodopsin and show that the arrangement of the helices is the same. In a tentative topographic model, helices 4, 6, and 7 are nearly perpendicular to the plane of the membrane. In the higher-resolution projection maps of frog rhodopsin, helix 5 looks more tilted than it appeared previously. The quality of the two frog rhodopsin crystals suggests that they would be suitable to obtain a three-dimensional structure in which all helices would be resolved.

Alternative translation initiation site usage results in two functionally distinct forms of the GATA-1 transcription factor.

GATA-1 is a zinc-finger transcription factor that plays a critical role in the normal development of hematopoietic cell lineages. In human and murine erythroid cells a previously undescribed 40-kDa protein is detected with GATA-1-specific antibodies. We show that the 40-kDa GATA-1 (GATA-1s) is produced by the use of an internal AUG initiation codon in the GATA-1 transcript. The GATA-1 proteins share identical binding activity and form heterodimers in erythroleukemic cells but differ in their transactivation potential and in their expression in developing mouse embryos.

Scrambling of the actin I gene in two Oxytricha species.

The DNA in a germ-line nucleus (a micronucleus) undergoes extensive processing when it develops into a somatic nucleus (a macronucleus) after cell mating in hypotrichous ciliates. Processing includes destruction of a large amount of spacer DNA between genes and excision of gene-sized molecules from chromosomes. Before processing, micronuclear genes are interrupted by numerous noncoding segments called internal eliminated sequences (IESs). The IESs are excised and destroyed, and the retained macro-nuclear-destined sequences (MDSs) are spliced. MDSs in some micronuclear genes are not in proper order and must be reordered during processing to create functional gene-sized molecules for the macronucleus. Here we report that the micronuclear actin I gene in Oxytricha trifallax WR consists of 10 MDSs and 9 IESs compared to the previously reported 9 MDSs and 8 IESs in the micronuclear actin I gene of Oxytricha nova. The MDSs in the actin I gene are scrambled in a similar pattern in the two species, but the positions of MDS-IES junctions are shifted by up to 14 bp for scrambled and 138 bp for the nonscrambled MDSs. The shifts in MDS-IES junctions create differences in the repeat sequences that are believed to guide MDS splicing. Also, the sizes and sequences of IESs in the micronuclear actin I genes are different in the two Oxytricha species. These observations give insight about the possible origins of IES insertion and MDS scrambling in evolution and show the extraordinary malleability of the germ-line DNA in hypotrichs.