Retinal isoforms of inosine 5'-monophosphate dehydrogenase type 1 are poor nucleic acid binding proteins

The RP 10 form of autosomal dominant retinitis pigmentosa (adRP) is caused by mutations in the widely expressed protein inosine 5′-monophosphate dehydrogenase type 1 (IMPDH1). These mutations have no effect on the enzymatic activity of IMPDH1, but do perturb the association of IMPDH1 with nucleic acids. Two newly discovered retinal-specific isoforms, IMPDH1(546) and IMPDH1(595), may provide the key to the photoreceptor specificity of disease [S.J. Bowne, Q. Liu, L.S. Sullivan, J. Zhu, C.J. Spellicy, C.B. Rickman, E.A. Pierce, S.P. Daiger, Invest. Ophthalmol. Vis. Sci. 47 (2006) 3754-3765]. Here we express and characterize the normal IMPDH1(546) and IMPDH1(595), together with their adRP-linked variants, D226N. The enzymatic activity of the purified IMPDH1(546), IMPDH1(595) and the D226N variants is indistinguishable from the canonical form. The intracellular distribution of IMPDH1(546) and IMPDH1(595) is also similar to the canonical IMPDH1 and unaffected by the D226N mutation. However, unlike the canonical IMPDH1, the retinal specific isoforms do not bind significant fractions of a random pool of oligonucleotides. This observation indicates that the C-terminal extension unique to the retinal isoforms blocks the nucleic acid binding site of IMPDH1, and thus uniquely regulates protein function within photoreceptors.     

IMP Dehydrogenase-Linked Retinitis Pigmentosa

Many retinal diseases are caused by mutations in photoreceptor-specific proteins. However, retinal disease can also result from mutations in widely expressed proteins. One such protein is inosine monophosphate dehydrogenase type 1 (IMPDH1), which catalyzes a key step in guanine nucleotide biosynthesis and also binds single-stranded nucleic acids. The pathogenic IMPDH1 mutations are in or near the CBS domains and do not affect enzymatic activity. However, these mutations do decrease the affinity and specificity of single-stranded nucleic acid binding. These observations suggest that IMPDH1 has a previously unappreciated role in RNA metabolism that is crucial for photoreceptor function.     

IMP dehydrogenase-linked retinitis pigmentosa

Many retinal diseases are caused by mutations in photoreceptor-specific proteins. However, retinal disease can also result from mutations in widely expressed proteins. One such protein is inosine monophosphate dehydrogenase type 1 (IMPDH1), which catalyzes a key step in guanine nucleotide biosynthesis and also binds single-stranded nucleic acids. The pathogenic IMPDH1 mutations are in or near the CBS domains and do not affect enzymatic activity. However, these mutations do decrease the affinity and specificity of single-stranded nucleic acid binding. These observations suggest that IMPDH1 has a previously unappreciated role in RNA metabolism that is crucial for photoreceptor function.     

FUS contributes to mTOR-dependent inhibition of translation

The amyotrophic lateral sclerosis (ALS) and frontotemporal dementia (FTD)–linked RNA-binding protein called FUS (fused in sarcoma) has been implicated in several aspects of RNA regulation, including mRNA translation. The mechanism by which FUS affects the translation of polyribosomes has not been established. Here we show that FUS can associate with stalled polyribosomes and that this association is sensitive to mTOR (mammalian target of rapamycin) kinase activity. Specifically, we show that FUS association with polyribosomes is increased by Torin1 treatment or when cells are cultured in nutrient-deficient media, but not when cells are treated with rapamycin, the allosteric inhibitor of mTORC1. Moreover, we report that FUS is necessary for efficient stalling of translation because deficient cells are refractory to the inhibition of mTOR-dependent signaling by Torin1. We also show that ALS-linked FUS mutants R521G and P525L associate abundantly with polyribosomes and decrease global protein synthesis. Importantly, the inhibitory effect on translation by FUS is impaired by mutations that reduce its RNA-binding affinity. These findings demonstrate that FUS is an important RNA-binding protein that mediates translational repression through mTOR-dependent signaling and that ALS-linked FUS mutants can cause a toxic gain of function in the cytoplasm by repressing the translation of mRNA at polyribosomes.     

Dynamic association of the fragile X mental retardation protein as a messenger ribonucleoprotein between microtubules and polyribosomes

The fragile X mental retardation protein (FMRP) is a selective RNA-binding protein that regulates translation and plays essential roles in synaptic function. FMRP is bound to specific mRNA ligands, actively transported into neuronal processes in a microtubule-dependent manner, and associated with polyribosomes engaged in translation elongation. However, the biochemical relationship between FMRP-microtubule association and FMRP-polyribosome association remains elusive. Here, we report that although the majority of FMRP is incorporated into elongating polyribosomes in the soluble cytoplasm, microtubule-associated FMRP is predominantly retained in translationally dormant, polyribosome-free messenger ribonucleoprotein (mRNP) complexes. Interestingly, FMRP-microtubule association is increased when mRNPs are dynamically released from polyribosomes as a result of inhibiting translation initiation. Furthermore, the I304N mutant FMRP that fails to be incorporated into polyribosomes is associated with microtubules in mRNP particles and transported into neuronal dendrites in a microtubule-dependent, 3,5-dihydroxyphenylglycine-stimulated manner with similar kinetics to that of wild-type FMRP. Hence, polyribosome-free FMRP-mRNP complexes travel on microtubules and wait for activity-dependent translational derepression at the site of function. The dual participation of FMRP in dormant mRNPs and polyribosomes suggests distinct roles of FMRP in dendritic transport and translational regulation, two distinct phases that control local protein production to accommodate synaptic plasticity.     

The effect of cycloheximide on incorporation of newly formed mRNA into membrane-bound polyribosomes in rat liver cells]

Incorporation kinetics of new synthesized mRNA into free and endoplasmic membrane-bound polyribosomes in the absence of normal translation (when protein synthesis in inhibited by 98% with cycloheximide) is studied. mRNA is found to incorporate into both free and bound polyribosomes. Relative content of new synthesized membrane-bound polyribosomes in the presence of cycloheximide within 2.5-4.5 hours is by 30-40% lower as compared with the control. This fact can be explained either by the absence of a growing peptide of a sufficient length, which is necessary for the formation of a part of membrane-bound polyribosomes, or by a restricted number of attachment sites on membranes as a result of delayed translation of mRNA in pre-existed polyribosomes. It is suggested that 1) the growing peptide in liver cells is responsible for the recognition of a membrane only under the formation of only one type of membrane-bound polyribosomes, or 2) the formation of all bound polyribosomes has a single mechanism and the growing peptide does not participates in the membrane recognition.     

Direct stimulation of translation by the multifunctional herpesvirus ICP27 protein

Herpes simplex virus type 1 (HSV-1) ICP27 protein is an essential regulator of viral gene expression with roles at various levels of RNA metabolism in the nucleus. Using the tethered function assay, we showed a cytoplasmic activity for ICP27 in directly enhancing mRNA translation in vivo in the absence of other viral factors. The region of ICP27 required for translational stimulation maps to the C terminus. Furthermore, in infected cells, ICP27 is associated with polyribosomes, indicating a function in translation during the lytic cycle.     

Accumulation of Rhodopsin in Late Endosomes Triggers Photoreceptor Cell Degeneration

Progressive retinal degeneration is the underlying feature of many human retinal dystrophies. Previous work using Drosophila as a model system and analysis of specific mutations in human rhodopsin have uncovered a connection between rhodopsin endocytosis and retinal degeneration. In these mutants, rhodopsin and its regulatory protein arrestin form stable complexes, and endocytosis of these complexes causes photoreceptor cell death. In this study we show that the internalized rhodopsin is not degraded in the lysosome but instead accumulates in the late endosomes. Using mutants that are defective in late endosome to lysosome trafficking, we were able to show that rhodopsin accumulates in endosomal compartments in these mutants and leads to light-dependent retinal degeneration. Moreover, we also show that in dying photoreceptors the internalized rhodopsin is not degraded but instead shows characteristics of insoluble proteins. Together these data implicate buildup of rhodopsin in the late endosomal system as a novel trigger of death of photoreceptor neurons.     

Messenger RNA is translated when associated with the cytoskeletal framework in normal and VSV-infected HeLa cells

When the cytoskeletal framework is prepared from suspension-grown HeLa by extraction with nonionic detergent, all the polyribosomes are associated with the framework while 80% of tRNA and the major portion of monoribosomes as well as 75% of the cell proteins are found in the soluble fraction. The mRNA of polyribosomes is bound to the cytoskeleton and these molecules remain attached even after polyribosomes are disassembled in vivo prior to extraction. Although all actively translating message molecules are attached to the framework, about one quarter of the poly(A)+ mRNA is free of the framework. The binding of message to the skeleton may be obligatory for translation. Upon infection with VSV, all the viral polyribosomes but not all the viral messages of the infected cell are associated with the cytoskeletal framework. Pulse-chase labeling shows that VSV messages initially associate with the framework and then later detach and cease translation. The mRNA for the viral glycoprotein (G), known to translate only on ribosomes bound to endoplasmic reticulum, is also retained by the detergent-extracted structure. It appears that the protein substructure of the endoplasmic reticulum which binds polyribosomes is a component of the cytoskeletal framework.     

Identification of mRNA/protein (mRNP) complexes containing Puralpha,mStaufen, fragile X protein,and myosin Va and their association with rough endoplasmic reticulum equipped with a kinesin motor

Puralpha, which is involved in diverse aspects of cellular functions, is strongly expressed in neuronal cytoplasm. Previously, we have reported that this protein controls BC1 RNA expression and its subsequent distribution within dendrites and that Puralpha is associated with polyribosomes. Here, we report that, following treatment with EDTA, Puralpha was released from polyribosomes in mRNA/protein complexes (mRNPs), which also contained mStaufen, Fragile X Mental Retardation Protein (FMRP), myosin Va, and other proteins with unknown functions. As the coimmunoprecipitation of these proteins by an anti-Puralpha antibody was abolished by RNase treatment, Puralpha may assist mRNP assembly in an RNA-dependent manner and be involved in targeting mRNPs to polyribosomes in cooperation with other RNA-binding proteins. The immunoprecipitation of mStaufen- and FMRP-containing mRNPs provided additional evidence that the anti-Puralpha detected structurally or functionally related mRNA subsets, which are distributed in the somatodendritic compartment. Furthermore, mRNPs appear to reside on rough endoplasmic reticulum equipped with a kinesin motor. Based on our present findings, we propose that this rough endoplasmic reticulum structure may form the molecular machinery that mediates and regulates multistep transport of polyribosomes along microtubules and actin filaments, as well as localized translation in the somatodendritic compartment.     

Repression of β-actin synthesis and persistence of ribosomal protein synthesis after infection of HeLa cells by herpes simplex virus type 1 infection are under translational control

Synthesis and assembly of ribosomal proteins into mature ribosomes persist late after infection of cells with herpes simplex virus type 1, while synthesis of β-actin is drastically shut off. Since mRNAs encoding ribosomal proteins and β-actin undergo concomitant degradation in infected HeLa cells, we have advanced the hypothesis that translation of the remaining mRNAs is differentially controlled after infection. The behaviour of mRNAs for three ribosomal proteins and for β-actin was investigated during the course of infection. In uninfected cells, β-actin mRNAs are associated with large polyribosomes, while only a part of ribosomal protein mRNAs are present in polyribosomes. In the course of infection, β-actin mRNAs are released from the ribosomes and are sequestered with 40S ribosomal subunits. Simultaneously, ribosomal protein mRNAs become associated with an increased number of ribosomes, even late in infection. In addition, virally induced phosphorylation of ribosomal protein S6 is more efficient in pre-existing ribosomes than in newly assembled ribosomes. These results indicate that in infected cells (i) translation of β-actin mRNA is selectively inhibited at a step necessary for binding the 60S ribosomal subunits; (ii) the rate of initiation of translation of ribosomal protein mRNAs increases after infection; and (iii) it is likely that translation of ribosomal protein mRNAs takes place preferentially on pre-existing ribosomes. Received: 5 February 1997 / Accepted: 28 May 1997     

Engineering a functional blue-wavelength-shifted rhodopsin mutant

We report an effort to engineer a functional, maximally blue-wavelength-shifted version of rhodopsin. Toward this goal, we first constructed and assayed a number of previously described mutations in the retinal binding pocket of rhodopsin, G90S, E122D, A292S, and A295S. Of these mutants, we found that only mutants E122D and A292S were like the wild type (WT). In contrast, mutant G90S exhibited a perturbed photobleaching spectrum, and mutant A295S exhibited decreased ability to activate transducin. We also identified and characterized a new blue-wavelength-shifting mutation (at site T118), a residue conserved in most opsin proteins. Interestingly, although residue T118 contacts the critically important C9-methyl group of the retinal chromophore, the T118A mutant exhibited no significant perturbation other than the blue-wavelength shift. In analyzing these mutants, we found that although several mutants exhibited different rates of retinal release, the activation energies of the retinal release were all approximately 20 kcal/mol, almost identical to the value found for WT rhodopsin. These latter results support the theory that chemical hydrolysis of the Schiff base is the rate-limiting step of the retinal release pathway. A combination of the functional blue-wavelength-shifting mutations was then used to generate a triple mutant (T118A/E122D/A292S) which exhibited a large blue-wavelength shift (absorption lambda(max) = 453 nm) while exhibiting minimal functional perturbation. Mutant T118A/E122D/A292S thus offers the possibility of a rhodopsin protein that can be worked with and studied using more ambient lighting conditions, and facilitates further study by fluorescence spectroscopy.     

The reduction of retinene1 to vitamina A1 in vitro

In the surviving vertebrate retina the retinene(1) liberated by bleaching rhodopsin is converted quantitatively to vitamin A(1). Recent chemical studies have indicated that in this process the aldehyde group of retinene(1) is reduced to the primary alcohol group of vitamin A(1) (Morton; Wald). Some time ago we brought this reaction into a cell-free brei prepared from cattle retinas. The retinas were frozen, desiccated, ground, and exhaustively extracted with petroleum ether; the resulting powder, stirred in neutral buffer solution and exposed to light, converted its retinene(1) completely to vitamin A(1). Some time ago also we observed that fresh rhodopsin solutions exhibit a special type of fading in darkness following exposure to light, which is absent from the same solutions after aging. We have confirmed Bliss's identification of this reaction as the conversion of retinene(1) to vitamin A(1). The system which reduces retinene(1) is fractionated anatomically in the retinal rods. The outer segments of the rods, broken off from the underlying retinal tissue, are unable to convert their retinene(1) to vitamin A(1). In the presence of a water extract of crushed retina they do perform this conversion. On the other hand the retinal tissue from which a water extract was taken has lost this capacity. Such washed retinal tissue is reactivated by returning the washings to the solid material. The activating effect of retinal washings on isolated outer limbs or washed retina is duplicated by a boiled muscle juice. This in turn can be replaced by reduced cozymase (reduced coenzyme I; DPN-H(2)); or by a mixture of DPN and fructosediphosphate. The conversion of retinene(1) to vitamin A(1) is therefore a reduction in which two atoms of hydrogen are transferred to retinene(1) from reduced cozymase. It is assumed that this reaction is catalyzed by an apoenzyme, retinene(1) reductase, present in the rod outer limb. This process is coupled with a second system in the outer segment which reduces DPN, using hexosediphosphate or one of its derivatives as hydrogen donor. This action of DPN brings a member of the vitamin B complex, nicotinic acid amide, into an auxiliary position in the rhodopsin system. In the isolated retina or in vitro systems the reduction of retinene(1) proceeds irreversibly. Yet this reduction must be balanced by an oxidative process elsewhere in the rhodopsin cycle, since through rhodopsin as intermediate vitamin A(1) regenerates retinene(1).     

Linking mRNA turnover and translation: assessing the polyribosomal association of mRNA decay factors and degradative intermediates

mRNA decay is a multistep process, often dependent on the active translation of an mRNA and on components of the translation apparatus. In Saccharomyces cerevisiae, several trans-acting factors required for mRNA decay associate with polyribosomes. We have explored the specificity of the interactions of these factors with polyribosomes, using sucrose gradient sedimentation analysis of the yeast UPF1 protein to test whether such interactions are altered when polyribosomes are disrupted by treatment with EDTA, digestion with micrococcal nuclease, or shifting of cells containing a temperature-sensitive eIF3 mutation to the nonpermissive temperature. These experiments, as well as others assaying the strength of factor association in high-salt sucrose gradients, lead us to conclude that Upf1p is tightly bound to the smallest polyribosomes, but not to the 40S or 60S ribosomal subunits. Similar experimental approaches were used to determine whether mRNA decay initiates prior to mRNA release from polyribosomes. Using sucrose gradient fractionation and Northern blotting, we can detect the polysomal association of a PGK1 mRNA decay intermediate and conclude that mRNA decay commences while an mRNA is still being translated.     

Deletions in exon 5 of the human rhodopsin gene causing a shift in the reading frame and autosomal dominant retinitis pigmentosa

By screening patients with autosomal dominant retinitis pigmentosa for mutations in the rhodopsin gene, two deletions (8bp and 1bp) have been identified in exon 5; these deletions cause a shift in the reading frame. The predicted proteins should be radically altered with translation continuing past the normal stop signal and resulting in a rhodopsin molecule that is, respectively, 1 and 10 amino acids longer. The clinical phenotype of the patients is described and is compared with that associated with other mutations in the same region of the gene.     

Crystallographic analysis of the primary photochemical reaction of squid rhodopsin

Visual signal transduction is initiated by the photoisomerization of 11-cis retinal upon rhodopsin ligation. Unlike vertebrate rhodopsin, which interacts with Gt-type G-protein to stimulate the cyclic GMP signaling pathway, invertebrate rhodopsin interacts with Gq-type G-protein to stimulate a signaling pathway that is based on inositol 1,4,5-triphosphate. Since the inositol 1,4,5-triphosphate signaling pathway is utilized by mammalian nonvisual pigments and a large number of G-protein-coupled receptors, it is important to elucidate how the activation mechanism of invertebrate rhodopsin differs from that of vertebrate rhodopsin. Previous crystallographic studies of squid and bovine rhodopsins have shown that there is a profound difference in the structures of the retinal-binding pockets of these photoreceptors. Here, we report the crystal structures of all-trans bathorhodopsin (Batho; the first photoreaction intermediate) and the artificial 9-cis isorhodopsin (Iso) of squid rhodopsin. Upon the formation of Batho, the central moiety of the retinal was observed to move largely towards the cytoplasmic side, while the Schiff base and the ionone ring underwent limited movements (i.e., the all-trans retinal in Batho took on a right-handed screwed configuration). Conversely, the 9-cis retinal in Iso took on a planar configuration. Our results suggest that the light energy absorbed by squid rhodopsin is mostly converted into the distortion energy of the retinal polyene chain and surrounding residues.     

The 5' end of the pea ferredoxin-1 mRNA mediates rapid and reversible light-directed changes in translation in tobacco

Ferredoxin-1 (Fed-1) mRNA contains an internal light response element (iLRE) that destabilizes mRNA when light-grown plants are placed in darkness. mRNAs containing this element dissociate from polyribosomes in the leaves of transgenic tobacco (Nicotiana tabacum) plants transferred to the dark for 2 d. Here, we report in vivo labeling experiments with a chloramphenicol acetyl transferase mRNA fused to the Fed-1 iLRE. Our data indicate that the Fed-1 iLRE mediates a rapid decline in translational efficiency and that iLRE-containing mRNAs dissociate from polyribosomes within 20 min after plants are transferred to darkness. Both events occur before the decline in mRNA abundance, and polyribosome association is rapidly reversible if plants are re-illuminated. These observations support a model in which Fed-1 mRNA in illuminated leaves is stabilized by its association with polyribosomes, and/or by translation. In darkness a large portion of the mRNA dissociates from polyribosomes and is subsequently degraded. We also show that a significant portion of total tobacco leaf mRNA is shifted from polyribosomal to non-polyribosomal fractions after 20 min in the dark, indicating that translation of other mRNAs is also rapidly down-regulated in response to darkness. This class includes some, but not all, cytoplasmic mRNAs encoding proteins involved in photosynthesis.