Molecular defects in Drosophila rhodopsin mutants

Four well characterized Drosophila rhodopsin (ninaE) mutants possess low levels of rhodopsin in their major class of photoreceptors. The molecular defect present in each strain was determined by isolating and sequencing the mutant genes. Two missense mutants encode proteins which have arginine residues positioned within membrane-spanning domains. The third missense mutant eliminates a proline found near an extracellular domain/membrane-spanning domain interface. Thus, the low levels of rhodopsin protein found in these mutants result directly from changes in protein structure which likely affect the positioning and stability of membrane-spanning domains. The fourth and most severe mutation is a nonsense mutation.     

Electrophysiological study of Drosophila rhodopsin mutants

Electrophysiological investigations were carried out on several independently isolated mutants of the ninaE gene, which encodes opsin in R1-6 photoreceptors, and a mutant of the ninaD gene, which is probably important in the formation of the rhodopsin chromophore. In these mutants, the rhodopsin content in R1-6 photoreceptors is reduced by 10(2)-10(6)-fold. Light-induced bumps recorded from even the most severely affected mutants are physiologically normal. Moreover, a detailed noise analysis shows that photoreceptor responses of both a ninaE mutant and a ninaD mutant follow the adapting bump model. Since any extensive rhodopsin-rhodopsin interactions are not likely in these mutants, the above results suggest that such interactions are not needed for the generation and adaptation of light-induced bumps. Mutant bumps are strikingly larger in amplitude than wild-type bumps. This difference is observed both in ninaD and ninaE mutants, which suggests that it is due to severe depletion of rhodopsin content, rather than to any specific alterations in the opsin protein. Lowering or buffering the intracellular calcium concentration by EGTA injection mimics the effects of the mutations on the bump amplitude, but, unlike the mutations, it also affects the latency and kinetics of light responses.     

Defective phospholipid metabolism in the retinular cell membrane of norpA (no receptor potential) visual transduction mutants of Drosophila

The phosphorylation of photoreceptor phospholipids in the three alleles of Drosophila visual mutants (norpA: no receptor potential A gene) was studied. In the normal strain, the gamma-32P of ATP was transferred mainly to phosphatidic acid (PA) and diphosphoinositide (DPI), while, in the mutants, we found that the phosphorylation of PA was drastically reduced, but that of DPI was not. The radioactivity incorporation into PA closely parallels with the degree of the mutant genes' expressivity among the three alleles of norpA tested. Therefore, the abnormality found in the phosphorylation of diglycerol to PA may be closely related to the primary mutant defect in the phototransduction mechanism.     

Drosophila mosaic screen identifies diehard mutants as norpA P24 suppressors

It is well-known that malfunctioning of the phototransduction mechanism stimulates the cell death machinery, resulting in retinal degeneration both in vertebrates and invertebrates. Genetic screens have often failed to identify modifiers underlying such degenerative syndromes because of the lethality associated with their fundamental function during development. A norpA ^P24 suppressor screen was successful performed with mosaic flies generated by the yeast site-specific recombination FLP-FRT system. Three independent diehard mutants, identified by mutagenizing the 2L FRT chromosome in the norpA ^P24 background, include both essential and non-essential mutations. Their suppressive effects on the norpA ^P24 -triggered retinal degeneration depend on the intensity and duration of light based on a deep pseudopupil analysis and histology. These results suggest that the suppressor screen using mosaic flies provides a valuable tool for recovering both essential and non-essential genes within the fundamental genetic pathways. Further studies of diehard mutants will provide insights into the disease mechanism that underlies the retinal degeneration of phototransduction mutants.     

Degeneration of photoreceptors in rhodopsin mutants of Drosophila

Five different, well-characterized mutants of the R1–6 rhodopsin gene (ninaE), which corresponds to the rod opsin gene of vertebrates, have been examined morphologically as a function of age (up to 9 weeks) to determine whether or not the photoreceptors degenerate and to assess the pattern of degeneration. Structural deterioration of R1–6 photoreceptors with age has been found in all five mutants. The structural pattern of degeneration is similar in the five mutants, but the time course of degeneration is allele dependent and varies greatly among the five, with the strongest alleles causing the fastest degeneration. The degeneration appears to be independent of either the illumination cycle to which the animals are exposed or the presence of screening pigments in the eye. Although the degeneration first appears in R1–6 photoreceptors, eventually R7/8 photoreceptors, which correspond to cones of vertebrates, are also affected. In many of these mutants, striking proliferations of membrane processes have been observed in the subrhabdomeric region of R1–6 photoreceptors. It is hypothesized that (1) this accumulation of membranes may be caused by the failure of newly synthesized membranes that are inserted into the base of microvilli to be assembled into R1–6 rhabdomeres and (2) this failure may be caused by the extremely low concentration of normal R1–6 rhodopsin in the nina E mutants. © 1992 John Wiley & Sons, Inc.     

Degeneration of photoreceptors in rhodopsin mutants of Drosophila.

Five different, well-characterized mutants of the R1-6 rhodopsin gene (ninaE), which corresponds to the rod opsin gene of vertebrates, have been examined morphologically as a function of age (up to 9 weeks) to determine whether or not the photoreceptors degenerate and to assess the pattern of degeneration. Structural deterioration of R1-6 photoreceptors with age has been found in all five mutants. The structural pattern of degeneration is similar in the five mutants, but the time course of degeneration is allele dependent and varies greatly among the five, with the strongest alleles causing the fastest degeneration. The degeneration appears to be independent of either the illumination cycle to which the animals are exposed or the presence of screening pigments in the eye. Although the degeneration first appears in R1-6 photoreceptors, eventually R7/8 photoreceptors, which correspond to cones of vertebrates, are also affected. In many of these mutants, striking proliferations of membrane processes have been observed in the subrhabdomeric region of R1-6 photoreceptors. It is hypothesized that (1) this accumulation of membranes may be caused by the failure of newly synthesized membranes that are inserted into the base of microvilli to be assembled into R1-6 rhabdomeres and (2) this failure may be caused by the extremely low concentration of normal R1-6 rhodopsin in the ninaE mutants.     

Gradients of differentiation in wild-type and bithorax mutants of Drosophila

We present evidence to show that differentiation in wing cells to produce hairs is synchronous over the distal 90% of the wing surface (approximately 28,000 cells). In spite of this synchrony within such a large area a temporal gradient exists between zones (in general anterior to posterior) on the animal surface with rather sharp boundaries in between. In order to evaluate the basis for the gradient we studied two mutants which carry different combinations of the genes of the bithorax complex. These were examined with respect to the temporal aspects of sensitivity to heat shock induction of the multihair phenocopy on wings and the time of initiation of the program of protein synthesis that is related to hair formation. Results show that the gradient observed is based on predetermined properties within specific areas of tissue rather than on the position of the cells in the animal.     

Suppression of wild-type rhodopsin maturation by mutants linked to autosomal dominant retinitis pigmentosa

Autosomal dominant retinitis pigmentosa (ADRP) has been linked to mutations in the gene encoding rhodopsin. Most RP-linked rhodopsin mutants are unable to fold correctly in the endoplasmic reticulum, are degraded by the ubiquitin proteasome system, and are highly prone to forming detergent-insoluble high molecular weight aggregates. Here we have reported that coexpression of folding-deficient, but not folding-proficient, ADRP-linked rhodopsin mutants impairs delivery of the wild-type protein to the plasma membrane. Fluorescence resonance energy transfer and co-precipitation studies revealed that mutant and wild-type rhodopsins form a high molecular weight, detergent-insoluble complex in which the two proteins are in close (<70 A) proximity. Co-expression of ARDP-linked rhodopsin folding-deficient mutants resulted in enhanced proteasome-mediated degradation and steady-state ubiquitination of the wild-type protein. These data suggested a dominant negative effect on conformational maturation that may underlie the dominant inheritance of ARDP.     

The mutagenic effects of diepoxybutane in wild-type and mutagen-sensitive mutants of Drosophila melanogaster

Genetic tests reported here demonstrate that among the DEB-induced mutants on 2 X-chromosome loci, viz. y and w, at a minimum, one-third are chromosome deletions. Among 11 MMS-sensitive mutants tested, 9 are also somatically sensitive to DEB. In addition direct genetic tests established that the capacity to repair DEB damage induced in sperm is impaired in females homozygous for 2 mutagen-sensitive mutants. By inference the same is also the case in females homozygous for 3 other mutagen-sensitive mutants.     

The central projections of mesothoracic sensory neurons in wild-type Drosophila and bithorax mutants

Sensory axons entering the CNS from large campaniform sensilla on the normal, mesothoracic wings of four-winged flies of the genotype $\text{bx}{}^3\text{pbx}\text{Ubx}{}^{130}$ follow the same two tracts as do the corresponding axons in wild-type flies. However, they produce more branches along the ventromedial tract (including some in the mesothoracic neuromere), more fibers crossing the midline in the metathorax, and several other modifications of the wild-type pattern. No morphological differences between the receptors in normal and mutant flies could be detected, even with the SEM. The extra branching and other altered characteristics are present in bithorax flies which are also genetically wingless and do not form the homeotic appendages, so they appear to be due to the $\text{bx}{}^3\text{pbx}\text{Ubx}{}^{130}$ or $\text{bx}{}^3\text{Ubx}{}^{130}$ genotype and not to some effect of the axons from the homeotic wings.     

Developmental analysis of lipids from wild-type and adipose60 mutants of Drosophila melanogaster

A comparative developmental analysis was made of lipids from wild-type and adipose60 (adp60) mutants of Drosophila melanogaster. The lipid content and fatty acid profiles of late third instar larvae, pupae, and mature adults were characterized in methanol:chloroform extracts utilizing thin layer and gas-liquid chromatography. Total lipid content of mutant adults was approximately twice that of the wild-type, but no genotypic differences in lipid content were seen in earlier developmental stages. No sexual dimorphism was observed in total lipid content, although fatty acid profiles revealed some sexual differences. Many stage-specific differences in fatty acid profiles and lipid content were developmentally associated with each genotype. Mutants tended to retain the larval phenotype in lipid content and, to a lesser extent, in fatty acid profile. In comparison to wild-type, mutants tended to have increased lipid saturation, especially in 16-carbon fatty acids in mature adults and in 18:0 fatty acids in late larvae and pupae. No significant difference between the mutants and wild-type appeared in the developmental profiles for 14:1 fatty acid isomers. Hence, adp60 does not alter the desaturation-elongation pathway, a secondary pathway for fatty acid desaturation in Drosophila, which received support from this analysis.     

Synthesis and degradation of alcohol dehydrogenase in wild-type and Adh-null activity mutants of Drosophila melanogaster

Both the amount and the size of alcohol dehydrogenase-like cross-reacting material was determined in 14 ethyl methanesulfonate (EMS)-induced alcohol dehydrogenase-null activity mutants. In 11 mutants cross-reacting material of the same apparent molecular weight as alcohol dehydrogenase was detected, while in 3 mutants no cross-reacting material was found. In all cases, the amount of cross-reacting material found in the mutants was lower than that in wild-type flies. High, intermediate, and low cross-reacting material-producing mutants showed similar initial rates of incorporation of labeled amino acid into alcohol dehydrogenase-like protein, presumably reflecting similar rates of synthesis. If the rate of synthesis of cross-reacting material is the same in the mutants as in the wild type, then the different levels of cross-reacting material must be due to different rates of degradation.Supported by NIH Grants GM-18254 and ES-01527 and DOE Contract EY-76-S-2965.     

The Drosophila melanogaster Ku70 coding sequence is wild-type in mus309 mutants

Drosophila melanogaster mus309 mutations have been identified as being in the Ku70 gene, encoding one subunit of the DNA-dependent protein kinase. However, recent work has suggested that these mutations are in the Bloom's syndrome homologue. Here, we demonstrate that the coding sequence of Ku70 gene is indeed wild-type in two mus309 mutant lines.     

Characterization of Drosophila melanogaster rhodopsin

A polypeptide present in Drosophila eye homogenates was identified as opsin. This polypeptide pI 7.8, with Mr 39,000 is a retina-specific protein. It has the spectral characteristics of rhodopsin contained in the R1-6 photoreceptors and decreases in amount with vitamin A deprivation. It contains a chromophore derived from vitamin A and linked to the protein moiety by a Schiff base. Moreover, the polypeptide identified corresponds to a retina-specific polypeptide that was shown previously to undergo light-dependent phosphorylation in living flies. These results indicate that many properties of Drosophila rhodopsin do not differ significantly from those reported for rhodopsins of other organisms. However, the isoelectric point of Drosophila opsin is considerably more basic than those reported for vertebrate rhodopsins.     

Proton movement and photointermediate kinetics in rhodopsin mutants

The role of ionizable amino acid side chains in the bovine rhodopsin activation mechanism was studied in mutants E134Q, E134R/R135E, H211F, and E122Q. All mutants exhibited bathorhodopsin stability on the 30 ns to 1 micros time scale similar to that of the wild type. Lumirhodopsin decay was also similar to that of the wild type except for the H211F mutant where early decay (20 micros) to a second form of lumirhodopsin was seen, followed by formation of an extremely long-lived Meta I(480) product (34 ms), an intermediate which forms to a much reduced extent, if at all, in dodecyl maltoside suspensions of wild-type rhodopsin. A smaller amount of a similar long-lived Meta I(480) product was seen after photolysis of E122Q, but E134Q and E134R/R135Q displayed kinetics much more similar to those of the wild type under these conditions (i.e., no Meta I(480) product). These results support the idea that specific interaction of His211 and Glu122 plays a significant role in deprotonation of the retinylidene Schiff base and receptor activation. Proton uptake measurements using bromcresol purple showed that E122Q was qualitatively similar to wild-type rhodopsin, with at least one proton being released during lumirhodopsin decay per Meta I(380) intermediate formed, followed by uptake of at least two protons per rhodopsin bleached on a time scale of tens of milliseconds. Different results were obtained for H211F, E134Q, and E134R/R135E, which all released approximately two protons per rhodopsin bleached. These results show that several ionizable groups besides the Schiff base imine are affected by the structural changes involved in rhodopsin activation. At least two proton uptake groups and probably at least one proton release group in addition to the Schiff base are present in rhodopsin.     

Constitutively active mutants of rhodopsin.

Two critical amino acids in the visual pigment rhodopsin are Lys-296, the site of attachment of retinal to the protein through a protonated Schiff base linkage, and Glu-113, the Schiff base counterion. Mutation of Lys-296 or Glu-113 results in constitutive activation of opsin, as assayed by its ability to activate transducin in the absence of added chromophore. We conclude that opsin is constrained to an inactive conformation by a salt bridge between Lys-296 and Glu-113. Recently, one of the mutants, K296E, was found in a family with retinitis pigmentosa, suggesting that degeneration of the photoreceptor cells in individuals with this mutation may result from persistent stimulation of the phototransduction pathway.     

Endosperm differentiation in barley wild-type and sex mutants

The cereal endosperm is a storage organ consisting of the central starchy endosperm surrounded by the aleurone layer. In barley, endosperm development is subdivisible into four main stages, i.e. the syncytial (I), the cellularization (II), the differentiation (III) and the maturation stage (IV). During stage I, a multinucleate syncytium is formed, which in stage II develops into the undifferentiated cellular endosperm. During stage III the cells of the endosperm differentiate into two types of aleurone cells (peripheral and modified) and three different starchy endosperm cell types (irregular, prismatic and subaleurone). To elucidate the ontogenetic relationship between the endosperm tissues, the phenotypes of sex (shrunken endosperm mutants expressing xenia) mutant endosperms were studied. These mutants can be classified into two groups, i.e. those in which development is arrested at one of the four wild-type stages described above, and those with abnormal development with new organizational patterns in the endosperm or with novel cell types. Based on these studies, it is suggested that the two endosperm halves represent cell lines derived from the two daughter nuclei of the primary endosperm nucleus, and that the prismatic starchy endosperm cells arise from a peripheral endosperm meristematic activity during stage III. Finally, a model for the main molecular events underlying the morphogenetic processes is discussed.     

Properties of photoreceptor-specific phospholipase C encoded by the norpA gene of Drosophila melanogaster.

Mutations in the norpA gene drastically affect the phototransduction process in Drosophila. To study the biochemical characteristics of the norpA protein and its cellular and subcellular distributions, we have generated antisera against the major gene product of norpA. The antisera recognize an eye-specific protein of 130-kDa relative molecular mass that is present in wild-type head extracts but not in those of strong norpA mutants. The protein is associated with membranes and can be extracted with high salt. Immunohistochemical analysis at the light and electron microscopic levels indicates that the protein is expressed in all adult photoreceptor cells and specifically localized within the rhabdomeres, preferentially adjacent to, but not within, the rhabdomeric membranes. The results of the present study strongly support the previous suggestion that the norpA gene encodes the major phosphoinositol-specific phospholipase C in the photoreceptors. Moreover, insofar as the rhabdomeres are specialized structures for photoreception and phototransduction, specific localization of the norpA protein within these structures, in close association with the membranes, is consistent with the proposal that it has an important role in phototransduction.     

A Drosophila metallophosphoesterase mediates deglycosylation of rhodopsin

Oligosaccharide chains of newly synthesized membrane receptors are trimmed and modified to optimize their trafficking and/or signalling before delivery to the cell surface. For most membrane receptors, the functional significance of oligosaccharide chain modification is unknown. During the maturation of Rh1 rhodopsin, a Drosophila light receptor, the oligosaccharide chain is trimmed extensively. Neither the functional significance of this modification nor the enzymes mediating this process are known. Here, we identify a dmppe (Drosophila metallophosphoesterase) mutant with incomplete deglycosylation of Rh1, and show that the retained oligosaccharide chain does not affect Rh1 localization or signalling. The incomplete deglycosylation, however, renders Rh1 more sensitive to endocytic degradation, and causes morphological and functional defects in photoreceptors of aged dmppe flies. We further demonstrate that the dMPPE protein functions as an Mn(2+)/Zn(2+)-dependent phosphoesterase and mediates in vivo dephosphorylation of α-Man-II. Most importantly, the dephosphorylated α-Man-II is required for the removal of the Rh1 oligosaccharide chain. These observations suggest that the glycosylation status of membrane proteins is controlled through phosphorylation/dephosphorylation, and that MPPE acts as the phosphoesterase in this regulation.