Fast Electrical Potential from a Long-Lived,Long-Wavelength Photoproduct of Fly Visual Pigment

A rapid electrical potential, which we have named the M-potential, can be obtained from the Drosophila eye using a high energy flash stimulus. The potential can be elicited from the normal fly, but it is especially prominent in the mutant norp A^P12 (a phototransduction mutant), particularly if the eye color pigments are genetically removed from the eye. Several lines of evidence suggest that the M-potential arises from photoexcitation of long-lived metarhodopsin. Photoexcitation of rhodopsin does not produce a comparable potential. The spectral sensitivity of the M-potential peaks at about 575 nm. The M-potential pigment (metarhodopsin) can be shown to photoconvert back and forth with a "silent pigment(s)" absorbing maximally at about 485 nm. The silent pigment presumably is rhodopsin. These results support the recent spectrophotometric findings that dipteran metarhodopsin absorbs at much longer wavelengths than rhodopsin. The M-potential probably is related to the photoproduct component of the early receptor potential (ERP). Two major differences between the M-potential and the classical ERP are: (a) Drosophila rhodopsin does not produce a rapid photoresponse, and (b) an anesthetized or freshly sacrificed animal does not yield the M-potential. As in the case of the ERP, the M-potential appears to be a response associated with a particular state of the fly visual pigment. Therefore, it should be useful in in vivo investigations of the fly visual pigment, about which little is known.     

Alteration of ribosomal protein S17 by mutation linked to neamine resistance in Escherichia coli: II. Localization of the amino acid replacement in protein S17 from a neaA mutant

A mutant of Escherichia coli strain K12S, nea^R301, resistant to the antibiotic neamine was found to have an altered 30 S ribosomal protein S17. The modification involves a change in the electrophoretic mobility of this protein. S17 proteins wore purified from the mutant and the parental strain, respectively, and the amino acid compositions of all tryptic peptides were compared. The results show that the mutational alteration involves a replacement of histidine by proline in peptide T8 from mutant nea^R301. The amino acid replacement is located at position 30 of the S17 protein chain. We conclude, therefore, that the mutation nea^R301 affects the structural gene for protein S17 (rps Q).     

Asynchronous activation of parental alleles at the tissue-specific gene loci observed on hybrid trout during early development

By using three genetic markers, the asynchronous activation of parental alleles during embryonic development was studied on interspecific hybrids between the male brown trout and the female rainbow trout. The genetic markers used were lactate dehydrogenase (LDH) A² as well as C subunits and alcohol dehydrogenase (ADH) subunits. Starch gel electrophoresis was utilized. The presence of LDH A² subunits was detected from a very early stage of development in whole embryo extracts. However, up to a few days after hatching (63rd day), A² subunits present were exclusively of the A^2R type derived from the rainbow mother. The coexistence of the products of both parental alleles at this gene locus became evident only at the 70th day. The LDH C subunits which occur only in the retina of the eye as well as the ADH subunits which occur only in liver made their first appearances at the 95th and 150th days, respectively. At these dates, only the maternally derived rainbow subunits were detectable. It took another 40 days for the paternally derived brown subunits to make their appearance.In Duarte, this work was supported in part by PHS grant CA-05138 from the National Cancer Institute, U.S. Public Health Service.     

Dominant negative mutations in the α-factor receptor, a G protein-coupled receptor encoded by the STE2 gene of the yeast Saccharomyces cerevisiae

The α-mating pheromone receptor encoded by the STE2 gene of the yeast Saccharomyces cerevisiae is a G protein-coupled receptor (GPCR) that is homologous to the large family of GPCRs that mediate multiple types of signal transduction in mammals. We have screened libraries of mutant receptors to identify dominant negative alleles that are capable of interfering with the function of a co-expressed normal receptor. Two dominant negative alleles have been recovered in this manner. In addition, we find that previously isolated loss-of-function mutations in the α-factor receptor exhibit dominant negative effects. Detection of the dominant effects requires high-level expression of the mutant receptors but does not require a high ratio of mutant to normal receptors. Cellular levels of the normal receptors are not affected by co-expression of the dominant negative alleles. Expression of the mutant receptors does not interfere with constitutive signaling in a strain that lacks the G protein α subunit encoded by GPA1, indicating that interference with signaling occurs at the level of the receptor or the interacting G protein. Expression of increased levels of G protein subunits partially reverses the dominant negative effects. The dominant negative behavior of the mutant receptors is diminished by deletion of the SST2 gene, which encodes an RGS (Regulator of G protein Signaling) protein involved in desensitization of pheromone signaling. The most likely explanation for the dominant negative effects of the mutations appears to be the existence of an interaction between unactivated receptors and the trimeric G protein that titrates the G protein away from the normal receptors or renders the G protein insensitive to receptor activation. This interaction appears to be mediated by the SST2 gene product.     

The structural gene for the ribosomal protein S18 in Escherichia coli. II. Chemical studies on the protein S18 having an altered electrophoretic mobility

A mutant of Escherichia coli strain CR341 has an altered 30 S ribosomal protein S18. The alteration involves a change in the electrophoretic mobility of S18. S18 proteins were purified from the mutant and the parent strain, respectively, and their amino acid composition and tryptic peptides were compared. The results have shown that the mutational alteration involves substitution of cysteine for arginine. In addition, we determined the electrophoretic mobility of S18 proteins modified by ethyleneimine. The modification, which involves conversion of cysteine residues to S-(2-aminoethyl)cysteine, causes a greater electrophoretic mobility increase in the mutant protein than in the wild type protein, resulting in identical mobilities for the aminoethylated proteins. This experiment gives further support to the conclusion that the original mobility difference between mutant and wild type proteins is due to the mutational substitution of cysteine for arginine. The S18 obtained from a recombinant was also studied. The recombinant protein was found to have the mobility of the wild type protein and the wild type primary structure, as judged by amino acid composition and tryptic peptide analysis. This recombinant was obtained from the mutant by introducing Hfr strain G10 chromosome segments in the region between 70 and 10 minutes, and not in the str-spc region at 64 minutes, as described in the preceding paper. These results, together with those in the preceding paper, show that the mutation studied here is in the structural gene for S18, and that it maps outside the str-spc region.     

The PS1 Hairpin of Mcm3 Is Essential for Viability and for DNA Unwinding In Vitro

The pre-sensor 1 (PS1) hairpin is found in ring-shaped helicases of the AAA+ family (ATPases associated with a variety of cellular activities) of proteins and is implicated in DNA translocation during DNA unwinding of archaeal mini-chromosome maintenance (MCM) and superfamily 3 viral replicative helicases. To determine whether the PS1 hairpin is required for the function of the eukaryotic replicative helicase, Mcm2-7 (also comprised of AAA+ proteins), we mutated the conserved lysine residue in the putative PS1 hairpin motif in each of the Saccharomyces cerevisiae Mcm2-7 subunits to alanine. Interestingly, only the PS1 hairpin of Mcm3 was essential for viability. While mutation of the PS1 hairpin in the remaining MCM subunits resulted in minimal phenotypes, with the exception of Mcm7 which showed slow growth under all conditions examined, the viable alleles were synthetic lethal with each other. Reconstituted Mcm2-7 containing Mcm3 with the PS1 mutation (Mcm3_K499A) had severely decreased helicase activity. The lack of helicase activity provides a probable explanation for the inviability of the mcm3 _K499A strain. The ATPase activity of Mcm2-7_3K499A was similar to the wild type complex, but its interaction with single-stranded DNA in an electrophoretic mobility shift assay and its associations in cells were subtly altered. Together, these findings indicate that the PS1 hairpins in the Mcm2-7 subunits have important and distinct functions, most evident by the essential nature of the Mcm3 PS1 hairpin in DNA unwinding.     

Agouti-Related Maturation and Tissue Distribution of oc-Melanocyte Stimulating Hormone in Wild-Type (AwJ/AwJ) and Mutant (Ay/a,a/a) Mice

Because of ectopic overproduction of agouti protein, yellow alleles (A^y and A^vy) of the murine agouti gene may secondarily modulate the synthesis, maturation (i.e., acetylation), and/or tissue deployment of α-Melanocyte Stimulating Hormone (MSH). We used HPLC to test the hypothesis that A^y/a mice exhibit altered concentrations of desacetyl-, monoacetyl-, and diacetyl-α-MSH in pituitaries, sera, and telogen hair bulbs when compared to black (a/a) mice. We also used RIA to measure total MSH in those same tissues of A^y/a, a/a, and white-bellied agouti (A^wJ/A^wJ) mice (Strain C57BL/6J). We found no evidence that A^y/a mice possessed an imbalance of des-, mono-, and diacetylated α-MSH species. However, radioimmunoassay (RIA) analyses of total MSH suggest that wild-type agouti mice (A^wJ/A^wJ) exhibited significantly decreased (P < 0.05) tissue levels of total α-MSH in pituitaries, sera, and regenerating hair bulbs when compared to those of mutant A^y/a and a/a mice.     

Protein phosphatase regulation by PRIP, a PLC-related catalytically inactive protein—Implications in the phospho-modulation of the GABAA receptor

PRIP, phospholipase C related, but catalytically inactive protein was first identified as a novel inositol 1,4,5-trisphosphate binding protein. It has a number of binding partners including protein phosphatase (PP1 and 2A), GABA_A receptor associated protein, and the β subunits of GABA_A receptors, in addition to inositol 1,4,5-trisphosphate. The identification of these molecules led us to examine the possible involvement of PRIP in the phospho-regulation of the β subunits of GABA_A receptors using hippocampal neurons prepared from PRIP-1 and 2 double knock-out (DKO) mice. Experiments were performed with special reference to the dephosphorylation processes of the β subunits. The phosphorylation of β3 subunits by the activation of protein kinase A in cortical neurons of the control mice continued for up to 5 min, even after washing out of the stimulus, followed by a gradual dephosphorylation. That of DKO mice gradually increased in spite of the lower phosphorylation levels induced by the stimulation. There was little difference in the amount of cellular cyclic AMP and protein kinase A activity between the control and mutant mice, indicating that phosphatases such as PP1 and PP2A are primarily involved in the difference. The time course of PP1 activity changes in the vicinity of the receptors in control mice corresponded to the phosphorylation of PRIP, while that of the mutant mice decreased with the period of the incubation. This is a good agreement with the suggestion that PRIP binds to and inactivates PP1, which is regulated by the phosphorylation of PRIP at threonine 94. These results suggest that PRIP plays an important role in controlling the dynamics of GABA_A receptor phosphorylation by through PP1 binding and, therefore, the efficacy of synaptic inhibition mediated by these receptors.     

Biochemical and molecular analysis of spontaneous and induced mutations at the mouse Mod-1 locus

We have analyzed five Mod-1 (malic enzyme) mutants at the molecular and biochemical level. Four of these mutants, three electrophoretic variants and one null mutant, were induced by ethylnitrosourea (ENU). Another null mutant was the result of a spontaneous mutation. All of these mutations were heritable in a Mendelian fashion and viable in the homozygous condition. Restriction endonuclease and Southern blot analysis revealed that the spontaneous null mutant possessed an altered restriction fragment banding pattern. All of the ENU-induced mutants possessed normal restriction fragment banding patterns. All 5 mutants produced normal levels of Mod-1-specific mRNA. Only the spontaneous null mutant produced mRNA with altered size, which was consistent with the altered DNA-banding pattern. MOD-1 enzyme activity levels were normal in the three ENU-induced mutants with altered electrophoretic mobility. Enzyme activity was significantly lower than normal in tissues from animals homozygous for the null alleles, however, using Western blot analysis, low but significant levels of MOD-1 protein in Mod-1 null homozygotes were detected.     

Inheritance and biochemical analysis of four electrophoretic variants of β-conglycinin from soybean

Summary Three genes which code for variant -conglycinin subunits were identified. Alleles Cgy ₁ ^S and Cgy ₂ ^S were codominant with Cgy ₁ and Cgy ₂ and produced and subunits, respectively, with reduced electrophoretic mobility. Allele Cgy ₃ ^D increased the mobility of at least one polypeptide in the subunit family and exhibited incomplete dominance. Gene loci Cgy ₂/Cgy ₂ ^S and Cgy ₃ ^D /cgy ₃ ^D were linked, whereas Cgy ₁/Cgy ₁ ^S / cgy ₁ segregated independently of the others. Techniques developed for purification of normal -conglycinin subunits were effective in purifying the altered subunits. Deglycosylated variant proteins from seeds containing the alleles Cgy ₁ ^S , Cgy ₂ ^S , or Cgy ₃ ^D also has altered mobility relative to deglycosylated normal proteins. Therefore, the altered subunits contained changes in their amino acid sequences rather than in their carbohydrate moieties. This interpretation is consistent with the observed codominant or incompletely dominant mode of inheritance for these alleles and suggests that each contains an altered nucleotide sequence in the structural gene. A fourth variant, which exhibited doublet and a electrophoretic bands, was inherited in a recessive fashion. Deglycosylated subunit proteins from this variant were identical in electrophoretic mobility to those of the deglycosylated normal protein. This suggests that the doublet phenotype resulted from an alteration in the carbohydrate moiety of these subunits. The gene or genes which condition this variant presumably are required for normal post-translational modification of the subunit carbohydrates and as such may be useful for investigating these events.Cooperative research of USDA-ARS and the Indiana Agric. Exp. Stn., Purdue Univ., West Lafayette, IN 47907, USA. Indiana Agric. Exp. Stn. Journal Article 10,323. Financial support from the American Soybean Research Foundation is gratefully acknowledged     

Gene control of soluble protein levels during development of abnormal abdomen in Drosophila

The mutant genotype Abnormal abdomen (A^53g) of Drosophila melanogaster causes an increase in the amount of soluble protein per fly when compared to a wild-type strain (Ore-R). This increase is first detected at 50 hr after puparium formation and is preceded 2 hr earlier by an increase in total RNA. A direct correlation is found between the expressivity of the A^53g mutation in the adult fly and the total soluble protein per mg body weight of that fly. Quantitative analyses of supernatant protein from mutant and wild-type flies on polyacrylamide disk gel electrophoresis reveal that the increases observed in the mutant are due to increases in specific electrophoretic classes of proteins and not to a general stimulation of all proteins. Reciprocal crosses between mutant and wild-type flies indicate that the penetrance and expressivity of the A^53g phenotype is under maternal control and that an increased soluble protein content in F1 flies is found only when the mutant genotype is contributed to the F1 through the maternal gamete.     

Human mitochondrial NDUFS3 protein bearing Leigh syndrome mutation is more prone to aggregation than its wild-type

NDUFS3 is an integral subunit of the Q module of the mitochondrial respiratory Complex-I. The combined mutation (T145I + R199W) in the subunit is reported to cause optic atrophy and Leigh syndrome accompanied by severe Complex-I deficiency. In the present study, we have cloned and overexpressed the human NDUFS3 subunit and its double mutant in a soluble form in Escherichia coli. The wild-type (w-t) and mutant proteins were purified to homogeneity through a serial two-step chromatographic purification procedure of anion exchange followed by size exclusion chromatography. The integrity and purity of the purified proteins was confirmed by Western blot analysis and MALDI-TOF/TOF. The conformational transitions of the purified subunits were studied through steady state as well as time resolved fluorescence and CD spectroscopy under various denaturing conditions. The mutant protein showed altered polarity around tryptophan residues, changed quenching parameters and also noticeably altered secondary and tertiary structure compared to the w-t protein. Mutant also exhibited a higher tendency than the w-t protein for aggregation which was examined using fluorescent (Thioflavin-T) and spectroscopic (Congo red) dye binding techniques. The pH stability of the w-t and mutant proteins varied at extreme acidic pH and the molten globule like structure of w-t at pH1 was absent in case of the mutant protein. Both the w-t and mutant proteins showed multi-step thermal and Gdn-HCl induced unfolding. Thus, the results provide insight into the alterations of NDUFS3 protein structure caused by the mutations, affecting the overall integrity of the protein and finally leading to disruption of Complex-I assembly.     

Internal and external membrane proteins of the cyanobacterium, Synechococcus cedrorum

The protein composition and architecture of the photosynthetic membranes from the cyanobacterium, Synechococcus cedrorum, were analyzed with the aid of site-specific labels. Using membranes labeled with ³⁵S, about 50 membrane proteins can be detected by sodium dodecyl sulfate acrylamide gel electrophoresis. Approximately half of the proteins are accessible to modification by the impermeant probe, lactoperoxidase, indicating that they have surface-exposed domains. At least six of these external proteins can be removed by EDTA washing; the correspondence in molecular weights between five of these EDTA-extractable proteins and those of typical chloroplast coupling factor preparations may indicate that they are subunits of a membrane-bound ATPase. The photoactive, lipophilic compound, [¹²⁵I]iodonaphthyl azide, was used to label protein domains in contact with the lipid bilayer. Iodonaphthyl azide modification led to a labeling pattern significantly different from that seen with lactoperoxidase. In particular, proteins in the 13 000–20 000 dalton range that were labeled poorly or not at all by lactoperoxidase were heavily modified by iodonaphthyl azide.Photosystem I and II particles, extracted from the membrane by digitonin treatment, were iodinated by lactoperoxidase after isolation. The PS I particles acted as a relatively tight complex, with most of the proteins remaining inaccessible to surface modification. The PS II particles, on the other hand, responded as a more open structure, with most of the subunits yielding to lactoperoxidase iodination. Similar studies on a highly fluorescent, temperature-sensitive mutant of S. cedrorum revealed a different organization of the PS II complex. This mutant, when grown at 40°C, inserts a 51 kdalton polypeptide in place of a 53 kdalton protein. This protein also replaces the 53 kdalton species in the PS II complex of the mutant after 40°C growth. The structure of this complex is altered in that more sites become accessible to lactoperoxidase. This is particularly true of the 51 kdalton protein, which is barely labeled in wild-type PS II complexes.     

A Two-state Model for the Diffusion of the A2A Adenosine Receptor in Hippocampal Neurons: AGONIST-INDUCED SWITCH TO SLOW MOBILITY IS MODIFIED BY SYNAPSE-ASSOCIATED PROTEIN 102 (SAP102)*

The A_2A receptor is a class A/rhodopsin-like G protein-coupled receptor. Coupling to its cognate protein, G_s, occurs via restricted collision coupling and is contingent on the presence of cholesterol. Agonist activation slows diffusion of the A_2A adenosine receptor in the lipid bilayer. We explored the contribution of the hydrophobic core and of the extended C terminus by examining diffusion of quantum dot-labeled receptor variants in dissociated hippocampal neurons. Single particle tracking of the A_2A receptor(1–311), which lacks the last 101 residues, revealed that agonist-induced confinement was abolished and that the agonist-induced decrease in diffusivity was reduced substantially. A fragment comprising the SH3 domain and the guanylate kinase domain of synapse-associated protein 102 (SAP102) was identified as a candidate interactor that bound to the A_2A receptor C terminus. Complex formation between the A_2A receptor and SAP102 was verified by coimmunoprecipitation and by tracking its impact on receptor diffusion. An analysis of all trajectories by a hidden Markov model was consistent with two diffusion states where agonist activation reduced the transition between the two states and, thus, promoted the accumulation of the A_2A receptor in the compartment with slow mobility. Overexpression of SAP102 precluded the access of the A_2A receptor to a compartment with restricted mobility. In contrast, a mutated A_2A receptor (with ³⁸³DVELL³⁸⁷ replaced by RVRAA) was insensitive to the action of SAP102. These observations show that the hydrophobic core per se does not fully account for the agonist-promoted change in mobility of the A_2A receptor. The extended carboxyl terminus allows for regulatory input by scaffolding molecules such as SAP102.     

Impairment of autophagosome-lysosome fusion in the buff mutant mice with the VPS33AD251E mutation

The HOPS (homotypic fusion and protein sorting) complex functions in endocytic and autophagic pathways in both lower eukaryotes and mammalian cells through its involvement in fusion events between endosomes and lysosomes or autophagosomes and lysosomes. However, the differential molecular mechanisms underlying these fusion processes are largely unknown. Buff (bf) is a mouse mutant that carries an Asp251-to-Glu point mutation (D251E) in the VPS33A protein, a tethering protein and a core subunit of the HOPS complex. Bf mice showed impaired spontaneous locomotor activity, motor learning, and autophagic activity. Although the gross anatomy of the brain was apparently normal, the number of Purkinje cells was significantly reduced. Furthermore, we found that fusion between autophagosomes and lysosomes was defective in bf cells without compromising the endocytic pathway. The direct association of mutant VPS33A^D251E with the autophagic SNARE complex, STX17 (syntaxin 17)-VAMP8-SNAP29, was enhanced. In addition, the VPS33A^D251E mutation enhanced interactions with other HOPS subunits, namely VPS41, VPS39, VPS18, and VPS11, except for VPS16. Reduction of the interactions between VPS33A^Y440D and several other HOPS subunits led to decreased association with STX17. These results suggest that the VPS33A^D251E mutation plays dual roles by increasing the HOPS complex assembly and its association with the autophagic SNARE complex, which selectively affects the autophagosome-lysosome fusion that impairs basal autophagic activity and induces Purkinje cell loss.     

Differential dynamics of membrane proteins in yeast

Lateral diffusion of lipids and proteins in yeast plasma membranes has been reported to be anomalously slow, and implicated as a possible reason for polarization in yeast. In order to gain insight into the observed slow diffusion in yeast membranes, we explored lateral diffusion of two proteins of different origin. We compared lateral dynamics of the Candida drug resistance protein-1 (Cdr1p), and the human serotonin_1A receptor (5-HT_1AR) by fluorescence recovery after photobleaching (FRAP). Our results show that while Cdr1p-GFP displays slow diffusion, the diffusion of 5-HT_1AR-EYFP is significantly faster. Interestingly, upon ergosterol depletion, the mobility of Cdr1p-GFP did not exhibit appreciable change, while 5-HT_1AR-EYFP mobility showed an increase. On the other hand, upon actin cytoskeleton destabilization, the mobile fraction of 5-HT_1AR-EYFP showed considerable increase, while the mobility of Cdr1p-GFP was not altered. Our results represent the first report on the dynamics of the important drug resistance protein Cdr1p and provide novel insight on diffusion of membrane proteins in yeast membranes.