Detection of radical species in haematin-catalysed retinoic acid 5,6-epoxidation by using h.p.l.c.-e.p.r. spectrometry.

E.p.r. signals were detected in an all-trans-retinoic acid/haematin incubation mixture by using an e.p.r. spin-trapping technique. The spin adducts are presumably attributable to some intermediates in haematin-catalysed retinoic acid 5,6-epoxidation, since addition of nitrosobenzene to the reaction mixture dose-dependently inhibited the epoxidation. Analysing the reaction mixture by h.p.l.c.-e.p.r. spectrometry resulted in the detection of three peaks (III-1, III-2, IV) ascribable to the radical species. Two (peaks III-1 and -2) of the three peaks, which appeared 10 min after the reaction had started, seem to be attributable to the radical species directly participating in the epoxidation. The radicals trapped by nitrosobenzene do not appear to be derived from active oxygen, since none of these peaks were detected in a similar h.p.l.c. analysis of O2- and OH.-generating systems. They are presumably derived from retinoic acid. This view is also supported by the following results: none of these peaks were detected in the h.p.l.c. elution profile of the reaction mixture when retinoic acid was absent; peaks III-1 and 2 were detected even under anaerobic conditions, and their peak heights were unchanged under aerobic conditions.     

The inner nuclear membrane protein p58 associates in vivo with a p58 kinase and the nuclear lamins.

p58, also referred to as the lamin B receptor, is an intrinsic protein of the inner nuclear membrane that binds in vitro to lamin B. Previous studies have demonstrated that p58 is phosphorylated in vivo and removal of its phosphate moieties affects lamin B binding. Using affinity-purified antipeptide antibodies, we have now immunoisolated p58 from bird erythrocyte lysates under isotonic, non-denaturing conditions. Analysis of the immunopurified material shows that five distinct proteins are tightly and specifically associated with p58. Two of these polypeptides can be identified as nuclear lamins A and B. The immunoisolate also contains a kinase activity that phosphorylates p58 in vivo and in vitro, exclusively at serine residues, as indicated by phosphoamino acid analysis and two-dimensional phosphopeptide mapping. Cell fractionation experiments and in vitro phosphorylation assays demonstrate that the p58 kinase resides in the nuclear envelope and is distinct from protein kinase A and cdc2 kinase, for both of which p58 is an in vitro substrate. These data suggest that p58 is interacting in vivo with a p58 kinase and the nuclear lamins.     

Heterozygous germline mutations in the p53 homolog p63 are the cause of EEC syndrome.

EEC syndrome is an autosomal dominant disorder characterized by ectrodactyly, ectodermal dysplasia, and facial clefts. We have mapped the genetic defect in several EEC syndrome families to a region of chromosome 3q27 previously implicated in the EEC-like disorder, limb mammary syndrome (LMS). Analysis of the p63 gene, a homolog of p53 located in the critical LMS/EEC interval, revealed heterozygous mutations in nine unrelated EEC families. Eight mutations result in amino acid substitutions that are predicted to abolish the DNA binding capacity of p63. The ninth is a frameshift mutation that affects the p63alpha, but not p63beta and p63gamma isotypes. Transactivation studies with these mutant p63 isotypes provide a molecular explanation for the dominant character of p63 mutations in EEC syndrome.     

Dynamic fatty acylation of p21N-ras.

To study the acylation of p21N-ras with palmitic acid we have used cells which express the human N-ras gene to high levels under control of the steroid-inducible MMTV--LTR promoter. Addition of [3H]palmitate to these cells resulted in detectable incorporation of label into p21N-ras within 5 min, which continued linearly for 30-60 min. Inhibition of protein synthesis for up to 24 h before addition of [3H]palmitate had no effect on acylation of p21N-ras, suggesting that this can occur as a late post-translational event. Acylated p21N-ras with a high SDS--PAGE mobility is found only in the membrane fraction, whereas approximately 50% of the [35S]methionine-labelled p21N-ras is cytoplasmic and has a lower mobility. Conversion of the acylated high mobility form to a deacylated form of slightly lower mobility can be achieved with neutral hydroxylamine, which is known to cleave thioesters. This treatment also results in partial removal of p21N-ras from the membranes. A remarkably high rate of turnover of the palmitate moiety can be demonstrated by pulse--chase studies (t1/2 approximately 20 min in serum-containing medium) which cannot be attributed to protein degradation. The data suggest an active acylation--deacylation cycle for p21N-ras, which may be involved in its proposed function as a signal transducing protein.     

Processing of the Epstein-Barr virus-encoded latent membrane protein p63/LMP.

We have analyzed the processing of the Epstein-Barr virus-encoded latent membrane protein (p63/LMP) in lymphoblastoid cell lines, Burkitt's lymphoma cell lines, and rodent fibroblasts transfected with the p63/LMP gene. Pulse-chase analysis by immunoprecipitation, under denaturing conditions, reveals a half-life of 2 h. This is due to turnover in the plasma membrane with cleavage of the protein, resulting in a 25,000-molecular-weight (p25) fragment derived from the carboxy-terminal portion of LMP. This fragment is rich in proline and acidic amino acids and sheds into the cytoplasm, where it appears to accumulate, being present in a six- to sevenfold molar excess over p63/LMP in immunoprecipitation analyses. p25 is, like p63/LMP, also phosphorylated (pp25) on serine and threonine residues, in the same ratio and to approximately the same extent as the intact p63/LMP molecule. Amino acid sequence analysis and carboxy-terminal labeling suggest that p25 is derived through a single cleavage adjacent to the sequence LGAPGGGPDNGPQDPD.     

Solution structure of the p53 regulatory domain of the p19Arf tumor suppressor protein

Arf is a tumor suppressor that regulates p53 function and is a frequent target for loss in human cancers. Through two novel mechanisms, Arf inhibits the oncoprotein Hdm2, a negative regulator of p53. (1) Arf inhibits the E3 ubiquitin ligase activity of Hdm2 that leads to p53 degradation, and (2) Arf sequesters Hdm2 within nucleoli. These activities of Arf promote p53-mediated cell cycle arrest and apoptosis. Fundamental to these processes are interactions between Arf and Hdm2. Here we show that a peptide containing the 37 N-terminal amino acids of mouse Arf (mArfN37) localizes to nucleoli, sequesters Hdm2 within nucleoli, and causes cell cycle arrest. Circular dichroism and NMR spectroscopy show that mArfN37 is largely unstructured under aqueous conditions; however, the peptide adopts two alpha-helices (helix 1, residues 4-14; and helix 2, residues 20-29) in 2,2,2-trifluoroethanol (TFE). Each helix contains an amino acid motif that is repeated twice in mArfN37, once in each helix. The two helices, however, do not interact but are connected by an apparently flexible linker. The repeated motif contains Arg residues spaced by a hydrophobic segment that may be involved in Hdm2 recognition and binding. The RRPR nucleolar localization signal, contained within residues 31-34, appears to be disordered under all conditions. The identification of two Arf structural modules suggests that short peptides containing the repeated motif may function as Arf mimics and may allow the design of small molecule Arf mimics in the future.     

Activated conformations of the ras-gene-encoded p21 protein. 1. An energy-refined structure for the normal p21 protein complexed with GDP.

A complete three-dimensional structure for the ras-gene-encoded p21 protein with Gly 12 and Gln 61, bound to GDP, has been constructed in four stages using the available alpha-carbon coordinates as deposited in the Brookhaven National Laboratories Protein Data Bank. No all-atom structure has been made available despite the fact that the first crystallographic structure for the p21 protein was reported almost four years ago. In the p21 protein, if amino acid substitutions are made at any one of a number of different positions in the amino acid sequence, the protein becomes permanently activated and causes malignant transformation of normal cells or, in some cell lines, differentiation and maturation. For example, all amino acids except Gly and Pro at position 12 result in an oncogenic protein; all amino acids except Gln, Glu and Pro at position 61 likewise cause malignant transformation of cells. We have constructed our all-atom structure of the non-oncogenic protein from the x-ray structure in order to determine how oncogenic amino acid substitutions affect the three-dimensional structure of this protein. In Stage 1 we generated a poly-alanine backbone (except at Gly and Pro residues) through the alpha-carbon structure, requiring the individual Ala, Pro or Gly residues to conform to standard amino acid geometry and to form trans-planar peptide bonds. Since no alpha-carbon coordinates for residues 60-65 have been determined, these residues were modeled by generating them in the extended conformation and then subjecting them to molecular dynamics using the computer application DISCOVER and energy minimization using DISCOVER and the ECEPP (Empirical Conformational Energies for Peptides Program). In Stage 2, the positions of residues that are homologous to corresponding residues of bacterial elongation factor Tu (EF-Tu) to which p21 bears an overall 40% sequence homology, were determined from their corresponding positions in a high-resolution structure of EF-Tu. Non-homologous loops were taken from the structure generated in Stage 1 and were placed between the appropriate homologous segments so as to connect them. In Stage 3, all bad contacts that occurred in this resulting structure were removed, and the coordinates of the alpha-carbon atoms were forced to superimpose as closely as possible on the corresponding atoms of the reference (x-ray) structure. Then the side chain positions of residues of the non-homologous loop regions were modeled using a combination of molecular dynamics and energy minimization using DISCOVER and ECEPP respectively.(ABSTRACT TRUNCATED AT 400 WORDS)     

Studies on p40, the leucine zipper motif-containing protein encoded by the first open reading frame of an active human LINE-1 transposable element.

Full-length human LINE-1 retrotransposons encode p40 proteins with varying electrophoretic mobilities under denaturing conditions. The p40 expressed from the first open reading frame in the LINE-1 copy designated L1.2A co-electrophoreses with the endogenous p40 in human teratocarcinoma cells. This finding is consistent with previous data indicating that L1.2A is an active element. The amino acid sequence in the central region of the L1.2A p40 accounts, at least in part, for its characteristic mobility. This region includes sequences which can, in principle, form a leucine zipper.     

Direct identification of palmitic acid as the lipid attached to p21ras.

p21v-H-ras, the transforming protein of Harvey murine sarcoma virus, contains a covalently attached lipid. Using thin-layer chromatography, we identified the acyl group as the 16-carbon saturated fatty acid palmitic acid. No myristic acid was detected in fatty acids released from in vivo-labeled p21v-H-ras. The p21v-K-ras protein encoded by Kirsten sarcoma virus was also palmitylated. The processing and acylation of p21v-K-ras however differed from that of p21v-H-ras. Three forms of [3H]palmitic acid-labeled p21ras proteins were detected in Kirsten sarcoma virus-transformed cells. This contrasted with Harvey sarcoma virus, in which two forms of p21v-H-ras contained palmitic acid. Analysis by partial proteolysis of p21v-H-ras labeled with [3H]palmitic acid suggested that all of the lipid found in intact p21v-H-ras was located in the C-terminal region. On sodium dodecyl sulfate-polyacrylamide gels, p21v-H-ras labeled with [3H]palmitic acid migrated slightly ahead of the majority of p21v-H-ras. Of the mature forms of p21v-H-ras, apparently only a subpopulation contains palmitic acid.     

cDNA cloning and immunological characterization of the rye grass allergen Lol p I.

The complete amino acid sequence of two "isoallergenic" forms of Lol p I, the major rye grass (Lolium perenne) pollen allergen, was deduced from cDNA sequence analysis. cDNA clones isolated from a Lolium perenne pollen library contained an open reading frame coding for a 240-amino acid protein. Comparison of the nucleotide and deduced amino acid sequence of two of these clones revealed four changes at the amino acid level and numerous nucleotide differences. Both clones contained one possible asparagine-linked glycosylation site. Northern blot analysis shows one RNA species of 1.2 kilobases. Based on the complete amino acid sequence of Lol p I, overlapping peptides covering the entire molecule were synthesized. Utilizing these peptides we have identified a determinant within the Lol p I molecule that is recognized by human leukocyte antigen class II-restricted T cells obtained from persons allergic to rye grass pollen.     

Ddi1p and Rad23p play a cooperative role as negative regulators in the PHO pathway in Saccharomyces cerevisiae

In Saccharomyces cerevisiae, the PHO pathway regulates expression of phosphate-responsive genes such as PHO5, which encodes repressible acid phosphatase (rAPase). In this pathway, Pho81p functions as an inhibitor of the cyclin-cyclin-dependent kinase (CDK) complex Pho80p-Pho85p. However, the mechanism regulating the inhibitory activity of Pho81p is poorly understood. Through use of the yeast two-hybrid system, we identified the UbL-UbA protein Ddi1p as a Pho81p-binding protein. Further, Pho81p levels were found to be low under high-phosphate condition and high during phosphate starvation, indicating that Pho81p is regulated by phosphate concentration. However, our results revealed that Ddi1p and its associated protein Rad23p are not involved in the decrease in Pho81p level under high-phosphate condition. Significantly, the Δddi1Δrad23 strain exhibited a remarkable increase in rAPase activity at an intermediate-phosphate concentration of 0.4 mM, suggesting that Ddi1p and Rad23p play a cooperative role as negative regulators in the PHO pathway.     

Lack of production of (p)ppGpp in Halobacterium volcanii under conditions that are effective in the eubacteria.

The stringent halobacterial strain Haloferax volcanii was subjected to a set of physiological conditions different from amino acid starvation that are known to cause production of guanosine polyphosphates [(p)pp Gpp] in eubacteria via the relA-independent (spoT) pathway. The conditions used were temperature upshift, treatment with cyanide, and total starvation. Under none of these conditions were detectable levels of (p)ppGpp observed. This result, in conjunction with our previous finding that (p)ppGpp synthesis does not occur under amino acid starvation, leads to the conclusion that in halobacteria both growth rate control and stringency are probably governed by mechanisms that operate in the absence of ppGpp. During exponential growth, a low level of phosphorylated compounds with electrophoretic mobilities similar, but not identical, to that of (p)ppGpp were observed. The intracellular concentration of these compounds increased considerably during the stationary phase of growth and with all of the treatments used. The compounds were identified as short-chain polyphosphates identical to those found under similar conditions in Saccharomyces cerevisiae.     

Transmembrane topology of the peroxin, Pex2p, an essential component for the peroxisome assembly.

The peroxisome biogenesis factor, peroxin Pex2p, is an integral membrane protein of peroxisomes [Tsukamoto, T., Miura, S., and Fujiki, Y. (1991) Nature 350, 77-81]. As a step toward elucidating the structure and biological function of Pex2p, we determined the transmembrane topology of Pex2p by expressing epitope-tagged rat Pex2p in COS-7 cells. Pex2p tagged with myc at the C-terminus was detected as a punctate staining pattern, when the cells were permeabilized with 50 microg/ml of digitonin, under which conditions intra-peroxisomal proteins such as PTS1-proteins are inaccessible to exogenous antibodies. N-terminally flag-tagged Pex2p was likewise detected upon the same treatment. These results strongly suggest that both the N- and C-terminal parts of Pex2p are exposed to the cytosol. The transmembrane orientation of Pex2p was also assessed by using rat liver peroxisomes and Pex2p region-specific antibodies. The two types of antibodies used, raised to the N- (amino acid residues 1-131) and C-terminal part (residues 226 to the C-terminus), respectively, specifically recognized Pex2p and immunoprecipitated intact, whole peroxisomes. Pex2p was not recognized by the antibodies when the peroxisomes were treated with Proteinase K. Furthermore, in situ crosslinking studies involving bifunctional reagents revealed an apparently dimeric form of Pex2p. Therefore, Pex2p is anchored to the peroxisomal membrane by two membrane-spanning segments, with its N- and C-terminal regions exposed to the cytosol.     

Activated Conformations of the ras-gene-Encoded p21 Protein. 1. An Energy-Refined Structure for the Normal p21 Protein Complexed with GDP

Abstract

A complete three-dimensional structure for the ras-gene-encoded p21 protein with Gly 12 and Gin 61, bound to GDP, has been constructed in four stages using the available α-carbon coordinates as deposited in the Brookhaven National Laboratories Protein Data Bank. No all-atom structure has been made available despite the fact that the first crystallographic structure for the p21 protein was reported almost four years ago. In the p21 protein, if amino acid substitutions are made at any one of a number of different positions in the amino acid sequence, the protein becomes permanently activated and causes malignant transformation of normal cells or, in some cell lines, differentiation and maturation. For example, all amino acids except Gly and Pro at position 12 result in an oncogenic protein; all amino acids except Gin, Glu and Pro at position 61 likewise cause malignant transformation of cells. We have constructed our all-atom structure of the non-oncogenic protein from the x-ray structure in order to determine how oncogenic amino acid substitutions affect the three-dimensional structure of this protein. In Stage 1 we generated a poly-alanine backbone (except at Gly and Pro residues) through the α-carbon structure, requiring the individual Ala, Pro or Gly residues to conform to standard amino acid geometry and to form trans-planar peptide bonds. Since no a-carbon coordinates for residues 60–65 have been determined these residues were modeled by generating them in the extended conformation and then subjecting them to molecular dynamics using the computer application DISCOVER and energy minimization using DISCOVER and the ECEPP (Empirical Conformational Energies for Peptides Program). In Stage 2, the positions of residues that are homologous to corresponding residues of bacterial elongation factor Tu (EF-Tu) to which p21 bears an overall 40% sequence homology, were determined from their corresponding positions in a high-resolution structure of EF-Tu. Non-homologous loops were taken from the structure generated in Stage 1 and were placed between the appropriate homologous segments so as to connect them. In Stage 3, all bad contacts that occurred in this resulting structure were removed, and the coordinates of the α-carbon atoms were forced to superimpose as closely as possible on the corresponding atoms of the reference (x-ray) structure. Then the side chain positions of residues of the nonhomologous loop regions were modeled using a combination of molecular dynamics and energy minimization using DISCOVER and ECEPP respectively. All of the residues of the structure were then allowed to move under restrained energy minimization where the restraints were gradually removed. In Stage 4, the nucleotide GOP was added to the model and further energy minimization was carried out. The energy of the protein-GOP complex was minimized by allowing the atoms of GOP to move with the protein held fixed and then by allowing both the nucleotide and the residues of the protein to move together. The reconstructed model agrees with the published features of the p21 protein-GOP complex including the hydrogen bonding scheme, the distribution of backbone dihedral angles, the residues contacting the nucleotide, and the orientation of loops with respect to one another in the protein. The structure also agrees with one that was predicted previously (Chen, J.M. et al., J. Biomol. Struct. Dynamics 6, 850–875 (1989)). In our molecular dynamics-energy minimization procedures, we also have been able to place all residues except Ala 66, which occurs in a poorly-defined region crystallographically, in local single residue minima, including residues reported to be in high energy regions in the x-ray structure. The constructed model can explain observed physical phenomena such as autophosphorylation by GTP on Thr 59 in proteins containing Thr in place of Ala 59.     

Cdc16p, Cdc23p and Cdc27p form a complex essential for mitosis.

Cdc16p, Cdc23p and Cdc27p are all essential proteins required for cell cycle progression through mitosis in Saccharomyces cerevisiae. All three proteins contain multiple tandemly repeated 34 amino acid tetratricopeptide repeats (TPRs). Using two independent assays, two-hybrid analysis in vivo and co-immunoprecipitation in vitro, we demonstrate that Cdc16p, Cdc23p and Cdc27p self associate and interact with one another to form a macromolecular complex. A temperature sensitive mutation in the most highly conserved TPR domain of Cdc27p results in a greatly reduced ability to interact with Cdc23p, but has no effect on interactions with wild-type Cdc27p or Cdc16p. The specificity of this effect indicates that TPRs can mediate protein-protein interactions and that this mutation may define an essential interaction for cell cycle progression in yeast. The conservation of at least two of the three proteins from yeast to man suggests that this protein complex is essential for mitosis in a wide range of eukaryotes.     

Antigenic determinants of the Ku (p70/p80) autoantigen are poorly conserved between species.

The Ku (p70/p80) autoantigen is a DNA-protein complex recognized by sera from certain patients with SLE and related diseases. Although human autoantibodies react with at least eight different epitopes of the human Ku complex, they had little reactivity with rodent Ku Ag on immunoblots. Small amounts of 70- and 80-kDa proteins were immunoprecipitated from murine cell extracts, however, suggesting that the Ku particle is not unique to human cells. This was confirmed by isolating cDNA clones encoding murine Ku Ag by plaque hybridization with a human p70 cDNA probe. The murine p70 cDNA clones had a deduced amino acid sequence 82.9% identical to that of human p70, and comparable amounts of murine and human p70 mRNA were detected in 3T3 and K562 cells, respectively. The poor reactivity of human autoantibodies with murine p70 was attributable to specific amino acid substitutions in an immunodominant conformational epitope located on amino acids 560-609 of human p70. Several amino acids critical for antigenicity of this region were defined by mutagenesis studies. Other conformational epitopes of Ku were also antigenically poorly conserved among species. Species-specific epitopes recognized by lupus autoantibodies are unusual but not unique to Ku. In general, poorly conserved autoepitopes have been conformational, rather than sequential, suggesting that the antigenicity of conformational epitopes may be particularly sensitive to evolutionary change.