Control of electron transfer in nitric-oxide synthases. Swapping of autoinhibitory elements among nitric-oxide synthase isoforms

To clarify the role of the autoinhibitory insert in the endothelial (eNOS) and neuronal (nNOS) nitric-oxide synthases, the insert was excised from nNOS and chimeras with its reductase domain; the eNOS and nNOS inserts were swapped and put into the normally insertless inducible (iNOS) isoform and chimeras with the iNOS reductase domain; and an RRKRK sequence in the insert suggested by earlier peptide studies to be important (Salerno, J. C., Harris, D. E., Irizarry, K., Patel, B., Morales, A. J., Smith, S. M., Martasek, P., Roman, L. J., Masters, B. S., Jones, C. L., Weissman, B. A., Lane, P., Liu, Q., and Gross, S. S. (1997) J. Biol. Chem. 272, 29769-29777) was mutated. Insertless nNOS required calmodulin (CaM) for normal NOS activity, but the Ca(2+) requirement for this activity was relaxed. Furthermore, insert deletion enhanced CaM-free electron transfer within nNOS and chimeras with the nNOS reductase, emphasizing the involvement of the insert in modulating electron transfer. Swapping the nNOS and eNOS inserts gave proteins with normal NOS activities, and the nNOS insert acted normally in raising the Ca(2+) dependence when placed in eNOS. Insertion of the eNOS insert into iNOS and chimeras with the iNOS reductase domain significantly lowered NOS activity, consistent with inhibition of electron transfer by the insert. Mutation of the eNOS RRKRK to an AAAAA sequence did not alter the eNOS Ca(2+) dependence but marginally inhibited electron transfer. The salt dependence suggests that the insert modulates electron transfer within the reductase domain prior to the heme/reductase interface. The results clarify the role of the reductase insert in modulating the Ca(2+) requirement, electron transfer rate, and overall activity of nNOS and eNOS.     

Identification and characterization of an autolysin gene, atlA, from Streptococcus criceti

AtlA of Streptococcus mutans is a major autolysin and belongs to glycoside hydrolase family 25 with cellosyl of Streptomyces coelicolor. The autolysin gene (atlA) encoding AtlA was identified from S. criceti. AtlA of S. criceti comprises the signal sequence in the N-terminus, the putative cell-wall-binding domain in the middle, and the catalytic domain in the C-terminus. Homology modeling analysis of the catalytic domain of AtlA showed the resemblance of the spatial arrangement of five amino acids around the predicted catalytic cavity to that of cellosyl. Recombinant AtlA and its four point mutants, D655A, D747A, W831A, and D849A, were evaluated on zymogram of S. criceti cells. Lytic activity was destroyed in the mutants D655A and D747A and diminished in the mutants W831A and D849A. These results suggest that Asp655 and Asp747 residues are critical for lytic activity and Trp831 and Asp849 residues are also associated with enzymatic activity.     

Heterologous expression of enzymopenic methemoglobinemia variants using a novel NADH:cytochrome c reductase fusion protein

Hereditary enzymopenic methemoglobinemia is a rare disease that predominantly results from defects in either the erythrocytic (type I) or microsomal (type II) forms of the enzyme NADH:cytochrome b5 reductase (EC 1.6.2.2). All 25 currently identified type I and type II methemoglobinemia mutants have been expressed in Escherichia coli using a novel six histidine-tagged rat cytochrome b5/cytochrome b5 reductase fusion protein designated NADH:cytochrome c reductase (H6NCR). All 25 H6NCR variants were isolated and demonstrated to result in two groups of expression products. The first group of 16 mutants, which included the majority of the type I mutants, included K116Q, P131L, L139P, T183S, M193V, S194P, P211L, L215P, A245T, A245V, C270Y, E279K, V305R, V319M, M340-, and F365-, and yielded full-length fusion proteins that retained variable levels of NADH:cytochrome c reductase (NADH:CR) activity, ranging from approximately 2% (M340-) to 92% (K116Q) of that of the wild-type fusion protein. In contrast, the remaining nine mutants that represented the majority of the type II variants, comprised a second group that included Y109*, R124Q, Q143*, R150*, P162H, V172M, R226*, C270R, and R285*, and resulted in truncated H6NCR variants that retained the amino-terminal cytochrome b5 domain but were devoid of NADH:CR activity due to the absence of the cytochrome b5 reductase flavin domain. Kinetic analyses of the first group of full-length mutant fusion proteins indicated that values for both kcat and Km(NADH) were decreased and increased, respectively, indicating that the various mutations affected both substrate affinity and/or turnover. However, for the second group, the truncated products were the result of incomplete production of the carboxyl-terminal flavin-containing domain or instability of the expression products due to improper folding and/or lack of flavin incorporation.     

Arginine 91 is not essential for flavin incorporation in hepatic cytochrome b(5) reductase

Cytochrome b(5) reductase (cb5r) catalyzes the transfer of reducing equivalents from NADH to cytochrome b(5). Utilizing an efficient heterologous expression system that produces a histidine-tagged form of the hydrophilic, diaphorase domain of the enzyme, site-directed mutagenesis has been used to generate cb5r mutants with substitutions at position 91 in the primary sequence. Arginine 91 is an important residue in binding the FAD prosthetic group and part of a conserved "RxY(T)(S)xx(S)(N)" sequence motif that is omnipresent in the "ferredoxin:NADP(+) reductase" family of flavoproteins. Arginine 91 was replaced with K, L, A, P, D, Q, and H residues, respectively, and all the mutant proteins purified to homogeneity. Individual mutants were expressed with variable efficiency and all exhibited molecular masses of approximately 32 kDa. With the exception of R91H, all the mutants retained visible absorption spectra typical of a flavoprotein, the former being produced as an apoprotein. Visible absorption spectra of R91A, L, and P were red shifted with maxima at 458 nm, while CD spectra indicated an altered FAD environment for all the mutants except R91K. Fluorescence spectra showed a reduced degree of intrinsic flavin fluorescence quenching for the R91K, A, and P, mutants, while thermal stability studies suggested all the mutants, except R91K, were somewhat less stable than the wild-type domain. Initial-rate kinetic measurements demonstrated that the mutants exhibited decreased NADH:ferricyanide reductase activity with the R91P mutant retaining the lowest activity, corresponding to a k(cat) of 283 s(-1) and a K(NADH)(m) of 105 microM, when compared to the wild-type domain (k(cat) = 800 s(-1) K(NADH)(m) = 6 microM). These results demonstrate that R91 is not essential for FAD binding in cb5r; however, mutation of R91 perturbs the flavin environment and alters both diaphorase substrate recognition and utilization.     

Alterations in the two globular domains or in the connecting alpha-helix of bacterial ribosomal protein L9 induces +1 frameshifts

The ribosomal 50S subunit protein L9, encoded by the gene rplI, is an elongated protein with an alpha-helix connecting the N- and C-terminal globular domains. We isolated rplI mutants that suppress the +1 frameshift mutation hisC3072 in Salmonella enterica serovar Typhimurium. These mutants have amino acid substitutions in the N-terminal domain (G24D) or in the C-terminal domain (I94S, A102D, G126V, and F132S) of L9. In addition, different one-base deletions in rplI altered either the final portion of the C terminus or removed the C-terminal domain with or without the connecting alpha-helix. An alanine-to-proline substitution at position 59 (A59P), which breaks the alpha-helix between the globular domains, induced +1 frameshifting, suggesting that the geometrical relationship between the N and C domains is important to maintain the reading frame. Except for the alterations G126V in the C terminus and A59P in the connecting alpha-helix, our results confirm earlier results obtained by using the phage T4 gene 60-based system to monitor bypassing. The way rplI mutations suppress various frameshift mutations suggests that bypassing of many codons from several takeoff and landing sites occurred instead of a specific frameshift forward at overlapping codons.     

Compensatory capsid protein mutations in cucumber mosaic virus confer systemic infectivity in squash (Cucurbita pepo)

Cucumber mosaic virus (CMV) systemically infects both tobacco and zucchini squash. CMV capsid protein loop mutants with single-amino-acid substitutions are unable to systemically infect squash, but they revert to a wild-type phenotype in the presence of an additional, specific single-site substitution. The D118A, T120A, D192A, and D197A loop mutants reverted to a wild-type phenotype but did so in combination with P56S, P77L, A162V, and I53F or T124I mutations, respectively. The possible effect of these compensatory mutations on other, nonsystemically infecting loop mutants was tested with the F117A mutant and found to be neutral, thus indicating a specificity to the observed changes.     

The sterol-sensing domain of the Niemann-Pick C1 (NPC1) protein regulates trafficking of low density lipoprotein cholesterol

The Niemann-Pick C1 (NPC1) protein is a key participant in intracellular sterol trafficking and regulation of cholesterol homeostasis. NPC1 contains a pentahelical region that is evolutionarily related to sterol-sensing domains found in other polytopic proteins involved in sterol interactions or sterol metabolism, including sterol regulatory element-binding protein cleavage-activating protein and hydroxymethylglutaryl-CoA reductase. To gain insight into the role of the sterol-sensing domain of NPC1, we examined the effect of point mutations in the NPC1 sterol-sensing domain on the trafficking of low density lipoprotein-derived cholesterol and sphingolipids. We show that an NPC1 P692S loss of function mutation results in decreased cholesterol delivery to the plasma membrane and endoplasmic reticulum. By contrast, NPC1 proteins carrying a L657F or D787N point mutation, which correspond to the activating SCAP L315F and D443N mutations, respectively, exhibit a gain of function phenotype. Specifically, cell lines expressing the NPC1 L657F or D787N mutations show a nearly 2-fold increase in the rates of low density lipoprotein cholesterol trafficking to the plasma membrane and to the endoplasmic reticulum, and more rapid suppression of sterol regulatory element-binding protein-dependent gene expression. Trafficking of sphingolipids is intact in the D787N and L657F cell lines. Our finding that D787N and L657F are activating NPC1 mutations provide evidence for a conserved mechanism for the sterol-sensing domain among cholesterol homeostatic proteins.     

Mutational and structural analysis of the nitrate reductase heme domain of Nicotiana plumbaginifolia.

We have analyzed four Nicotiana plumbaginifolia null mutants presumably affected in the heme domain of nitrate reductase. The DNA sequence of this domain has been determined for each mutant and for the wild type. Two mutations were identified as single base changes leading to, respectively, the substitution of a histidine residue by an asparagine (mutant E56) and to the appearance of an ochre stop codon (mutant E64). Based on the amino acid sequence homology between the nitrate reductase heme domain and mammalian cytochrome b5, we have predicted the three-dimensional structure of this domain. This showed that the nitrate reductase heme domain is structurally very similar to cytochrome b5 and it also confirmed that the residue involved in E56 mutation is one of the two heme-binding histidines. The two other mutations (mutants A1 and K21) were found to be, respectively, -1 and +1 frameshift mutations resulting in the appearance of an opal stop codon. These sequence data confirmed previous genetic and biochemical hypotheses on nitrate reductase-deficient mutants. Northern blot analysis of these mutants indicated that mutant E56 overexpressed the nitrate reductase mRNA, whereas the nonsense mutations present in the other mutants led to reduced levels of nitrate reductase mRNA.     

Functional correlation between a novel amino acid insertion at codon 19 in the protease of human immunodeficiency virus type 1 and polymorphism in the p1/p6 Gag cleavage site in drug resistance and replication fitness

Population-based sequence analysis revealed the presence of a variant of human immunodeficiency virus type 1 (HIV-1) containing an insertion of amino acid Ile in the protease gene at codon 19 (19I) and amino acid substitutions in the protease at codons 21 (E21D) and 22 (A22V) along with multiple mutations associated with drug resistance, M46I/P63L/A71V/I84V/I93L, in a patient who had failed protease inhibitor (PI) therapy. Longitudinal analysis revealed that the P63L/A71V/I93L changes were present prior to PI therapy. Polymorphisms in the Gag sequence were only seen in the p1/p6 cleavage site at the P1' position (Leu to Pro) and the P5' position (Pro to Leu). To characterize the role of these mutations in drug susceptibility and replication capacity, a chimeric HIV-1 strain containing the 19I/E21D/A22V mutations with the M46I/P63L/A71V/I84V/I93L and p1/p6 mutations was constructed. The chimera displayed high-level resistance to multiple PIs, but not to lopinavir, and grew to 30% of that of the wild type. To determine the relative contribution of each mutation to the phenotypic characteristic of the virus, a series of mutants was constructed using site-directed mutagenesis. A high level of resistance was only seen in mutants containing the 19I/A22V and p1/p6 mutations. The E21D mutation enhanced viral replication. These results suggest that the combination of the 19I/E21D/A22V mutations may emerge and lead to high-level resistance to multiple PIs. The combination of the 19I/A22V mutations may be associated with PI resistance; however, the drug resistance may be caused by the presence of a unique set of mutations in the p1/p6 mutations. The E21D mutation contributes to replication fitness rather than drug resistance.     

Identification of an anchor residue for CheA-CheY interactions in the chemotaxis system of Escherichia coli

Transfer of a phosphoryl group from autophosphorylated CheA (P-CheA) to CheY is an important step in the bacterial chemotaxis signal transduction pathway. This reaction involves CheY (i) binding to the P2 domain of P-CheA and then (ii) acquiring the phosphoryl group from the P1 domain. Crystal structures indicated numerous side chain interactions at the CheY-P2 binding interface. To investigate the individual contributions of the P2 side chains involved in these contacts, we analyzed the effects of eight alanine substitution mutations on CheA-CheY binding interactions. An F214A substitution in P2 caused ～1,000-fold reduction in CheA-CheY binding affinity, while Ala substitutions at other P2 positions had small effects (E171A, E178A, and I216A) or no detectable effects (H181A, D202A, D207A, and C213A) on binding affinity. These results are discussed in relation to previous in silico predictions of hot-spot and anchor positions at the CheA-CheY interface. We also investigated the consequences of these mutations for chemotaxis signal transduction in living cells. CheA(F214A) was defective in mediating localization of CheY-YFP to the large clusters of signaling proteins that form at the poles of Escherichia coli cells, while the other CheA variants did not differ from wild-type (wt) CheA (CheA(wt)) in this regard. In our set of mutants, only CheA(F214A) exhibited a markedly diminished ability to support chemotaxis in motility agar assays. Surprisingly, however, in FRET assays that monitored receptor-regulated production of phospho-CheY, CheA(F214A) (and each of the other Ala substitution mutants) performed just as well as CheA(wt). Overall, our findings indicate that F214 serves as an anchor residue at the CheA-CheY interface and makes an important contribution to the binding energy in vitro and in vivo; however, loss of this contribution does not have a large negative effect on the overall ability of the signaling pathway to modulate P-CheY levels in response to chemoattractants.     

Gating effects of mutations in the Cav3.2 T-type calcium channel associated with childhood absence epilepsy

Childhood absence epilepsy (CAE) is a type of generalized epilepsy observed in 2-10% of epileptic children. In a recent study by Chen et al. (Chen, Y., Lu, J., Pan, H., Zhang, Y., Wu, H., Xu, K., Liu, X., Jiang, Y., Bao, X., Yao, Z., Ding, K., Lo, W. H., Qiang, B., Chan, P., Shen, Y., and Wu, X. (2003) Ann. Neurol. 54, 239-243) 12 missense mutations were identified in the CACNA1H (Ca(v)3.2) gene in 14 of 118 patients with CAE but not in 230 control individuals. We have functionally characterized five of these mutations (F161L, E282K, C456S, V831M, and D1463N) using rat Ca(v)3.2 and whole-cell patch clamp recordings in transfected HEK293 cells. Two of the mutations, F161L and E282K, mediated an approximately 10-mV hyperpolarizing shift in the half-activation potential. Mutation V831M caused a approximately 50% slowing of inactivation relative to control and shifted half-inactivation potential approximately 10 mV toward more depolarized potentials. Mean time to peak was significantly increased by mutation V831M but was unchanged for all others. No resolvable changes in the parameters of the IV relation or current kinetics were observed with the remaining mutations. The findings suggest that several of the Ca(v)3.2 mutants allow for greater calcium influx during physiological activation and in the case of F161L and E282K can result in channel openings at more hyperpolarized (close to resting) potentials. This may underlie the propensity for seizures in patients with CAE.     

Introducing Wilson disease mutations into the zinc-transporting P-type ATPase of Escherichia coli. The mutation P634L in the 'hinge' motif (GDGXNDXP) perturbs the formation of the E2P state.

ZntA, a bacterial zinc-transporting P-type ATPase, is homologous to two human ATPases mutated in Menkes and Wilson diseases. To explore the roles of the bacterial ATPase residues homologous to those involved in the human diseases, we have introduced several point mutations into ZntA. The mutants P401L, D628A and P634L correspond to the Wilson disease mutations P992L, D1267A and P1273L, respectively. The mutations D628A and P634L are located in the C-terminal part of the phosphorylation domain in the so-called hinge motif conserved in all P-type ATPases. P401L resides near the N-terminal portion of the phosphorylation domain whereas the mutations H475Q and P476L affect the heavy metal ATPase-specific HP motif in the nucleotide binding domain. All mutants show reduced ATPase activity corresponding 0-37% of the wild-type activity. The mutants P401L, H475Q and P476L are poorly phosphorylated by both ATP and P(i). Their dephosphorylation rates are slow. The D628A mutant is inactive and cannot be phosphorylated at all. In contrast, the mutant P634L six residues apart in the same domain shows normal phosphorylation by ATP. However, phosphorylation by P(i) is almost absent. In the absence of added ADP the P634L mutant dephosphorylates much more slowly than the wild-type, whereas in the presence of ADP the dephosphorylation rate is faster than that of the wild-type. We conclude that the mutation P634L affects the conversion between the states E1P and E2P so that the mutant favors the E1 or E1P state.     

The identification of a domain in Escherichia coli elongation factor Tu that interacts with elongation factor Ts.

A method has been developed to search for the elongation factor Tu (EF-Tu) domain(s) that interact with elongation factor Ts (EF-Ts). This method is based on the suppression of Escherichia coli EF-Tu-dominant negative mutation K136E, a mutation that exerts its effect by sequestering EF-Ts. We have identified nine single-amino acid- substituted suppression mutations in the region 146-199 of EF-Tu. These mutations are R154C, P168L, A174V, K176E, D181G, E190K, D196G, S197F, and I199V. All suppression mutations but one (R154C) significantly affect EF-Tu's ability to interact with EF-Ts under equilibrium conditions. Moreover, with the exception of mutation A174V, the GDP affinity of EF-Tu appears to be relatively unaffected by these mutations. These results suggest that the domain of residues 154 to 199 on EF-Tu is involved in interacting with EF-Ts. These suppression mutations are also capable of suppressing dominant negative mutants N135D and N135I to various degrees. This suggests that dominant negative mutants N135D and N135I are likely to have the same molecular basis as the K136E mutation. The method we have developed in this study is versatile and can be readily adapted to map other regions of EF-Tu. A model of EF-Ts-catalyzed guanine-nucleotide exchange is discussed.     

Dominant and recessive distal renal tubular acidosis mutations of kidney anion exchanger 1 induce distinct trafficking defects in MDCK cells

Distal renal tubular acidosis (dRTA), a kidney disease resulting in defective urinary acidification, can be caused by dominant or recessive mutations in the kidney Cl-/HCO3- anion exchanger (kAE1), a glycoprotein expressed in the basolateral membrane of alpha-intercalated cells. We compared the effect of two dominant (R589H and S613F) and two recessive (S773P and G701D) dRTA point mutations on kAE1 trafficking in Madin-Darby canine kidney (MDCK) epithelial cells. In contrast to wild-type (WT) kAE1 that was localized to the basolateral membrane, the dominant mutants (kAE1 R589H and S613F) were retained in the endoplasmic reticulum (ER) in MDCK cells, with a few cells showing in addition some apical localization. The recessive mutant kAE1 S773P, while misfolded and largely retained in the ER in non-polarized MDCK cells, was targeted to the basolateral membrane after polarization. The other recessive mutants, kAE1 G701D and designed G701E, G701R but not G701A or G701L mutants, were localized to the Golgi in both non-polarized and polarized cells. The results suggest that introduction of a polar mutation into a transmembrane segment resulted in Golgi retention of the recessive G701D mutant. When coexpressed, the dominant mutants retained kAE1 WT intracellularly, while the recessive mutants did not. Coexpression of recessive G701D and S773P mutants in polarized cells showed that these proteins could interact, yet no G701D mutant was detected at the basolateral membrane. Therefore, compound heterozygous patients expressing both recessive mutants (G701D/S773P) likely developed dRTA due to the lack of a functional kAE1 at the basolateral surface of alpha-intercalated cells.     

Overall Prevalence and Distribution of Knockdown Resistance (kdr) Mutations in Aedes aegypti from Mandalay Region,Myanmar

Knockdown resistance (kdr) mutations in the voltage-gated sodium channel (VGSC) of mosquitoes confer resistance to insecticides. Although insecticide resistance has been suspected to be widespread in the natural population of Aedes aegypti in Myanmar, only limited information is currently available. The overall prevalence and distribution of kdr mutations was analyzed in Ae. aegypti from Mandalay areas, Myanmar. Sequence analysis of the VGSC in Ae. aegypti from Myanmar revealed amino acid mutations at 13 and 11 positions in domains II and III of VGSC, respectively. High frequencies of S989P (68.6%), V1016G (73.5%), and F1534C (40.1%) were found in domains II and III. T1520I was also found, but the frequency was low (8.1%). The frequency of S989P/V1016G was high (55.0%), and the frequencies of V1016G/F1534C and S989P/V1016G/F1534C were also high at 30.1% and 23.5%, respectively. Novel mutations in domain II (L963Q, M976I, V977A, M994T, L995F, V996M/A, D998N, V999A, N1013D, and F1020S) and domain III (K1514R, Y1523H, V1529A, F1534L, F1537S, V1546A, F1551S, G1581D, and K1584R) were also identified. These results collectively suggest that high frequencies of kdr mutations were identified in Myanmar Ae. aegypti, indicating a high level of insecticide resistance.     

Escherichia coli glutamyl-tRNA reductase. Trapping the thioester intermediate

In the first step of tetrapyrrole biosynthesis in Escherichia coli, glutamyl-tRNA reductase (GluTR, encoded by hemA) catalyzes the NADPH-dependent reduction of glutamyl-tRNA to glutamate-1-semialdehyde. Soluble homodimeric E. coli GluTR was made by co-expressing the hemA gene and the chaperone genes dnaJK and grpE. During Mg(2+)-stimulated catalysis, the reactive sulfhydryl group of Cys-50 in the E. coli enzyme attacks the alpha-carbonyl group of the tRNA-bound glutamate. The resulting thioester intermediate was trapped and detected by autoradiography. In the presence of NADPH, the end product, glutamate-1-semialdehyde, is formed. In the absence of NADPH, E. coli GluTR exhibited substrate esterase activity. The in vitro synthesized unmodified glutamyl-tRNA was an acceptable substrate for E. coli GluTR. Eight 5-aminolevulinic acid auxotrophic E. coli hemA mutants were genetically selected, and the corresponding mutations were determined. Most of the recombinant purified mutant GluTR enzymes lacked detectable activity. Based on the Methanopyrus kandleri GluTR structure, the positions of the amino acid exchanges are close to the catalytic domain (G7D, E114K, R314C, S22L/S164F, G44C/S105N/A326T, G106N, S145F). Only GluTR G191D (affected in NADPH binding) revealed esterase but no reductase activity.     

Differential effects of mutations in the chromophore pocket of recombinant phytochrome on chromoprotein assembly and Pr-to-Pfr photoconversion.

Site-directed mutagenesis was performed with the chromophore-bearing N-terminal domain of oat phytochrome A apoprotein (amino acid residues 1-595). Except for Trp366, which was replaced by Phe (W366F), all the residues exchanged are in close proximity to the chromophore-binding Cys321 (i.e. P318A, P318K, H319L, S320K, H322L and the double mutant L323R/Q324D). The mutants were characterized by their absorption maxima, and the kinetics of chromophore-binding and the Pr-->Pfr conversion. The strongest effect of mutation on the chromoprotein assembly, leading to an almost complete loss of the chromophore binding capability, was found for the exchanges of His322 by Leu (H322L) and Pro318 by Lys (P318K), whereas a corresponding alanine mutant (P318A) showed wild-type behavior. The second histidine (H319) is also involved in chromophore fixation, as indicated by a slower assembly rate upon mutation (H319L). For the other mutants, an assembly process very similar to that of the wild-type protein was found. The light-induced Pr-->Pfr conversion kinetics is altered in the mutations H319L and S320K and in the double mutant L323R/Q324D, all of which exhibited a significantly faster I700 decay and accelerated Pfr formation. P318 is also involved in the Pr-->Pfr conversion, the millisecond steps (formation of Pfr) being significantly slower for P318A. Lacking sufficient amounts of W366F, assembly kinetics could not be determined in this case, while the fully assembled mutant underwent the Pr-->Pfr conversion with kinetics similar to wild-type protein.     

Impact of autosomal recessive juvenile Parkinson's disease mutations on the structure and interactions of the parkin ubiquitin-like domain

Autosomal recessive juvenile parkinsonism (ARJP) is an early onset familial form of Parkinson's disease. Approximately 50% of all ARJP cases are attributed to mutations in the gene park2, coding for the protein parkin. Parkin is a multidomain E3 ubiquitin ligase with six distinct domains including an N-terminal ubiquitin-like (Ubl) domain. In this work we examined the structure, stability, and interactions of the parkin Ubl domain containing most ARJP causative mutations. Using NMR spectroscopy we show that the Ubl domain proteins containing the ARJP substitutions G12R, D18N, K32T, R33Q, P37L, and K48A retained a similar three-dimensional fold as the Ubl domain, while at least one other (V15M) had altered packing. Four substitutions (A31D, R42P, A46P, and V56E) result in poor folding of the domain, while one protein (T55I) showed evidence of heterogeneity and aggregation. Further, of the substitutions that maintained their three-dimensional fold, we found that four of these (V15M, K32T, R33Q, and P37L) lead to impaired function due to decreased ability to interact with the 19S regulatory subunit S5a. Three substitutions (G12R, D18N, and Q34R) with an uncertain role in the disease did not alter the three-dimensional fold or S5a interaction. This work provides the first extensive characterization of the structural effects of causative mutations within the ubiquitin-like domain in ARJP.     

Nitric oxide reduction, the last step in denitrification by Fusarium oxysporum, is obligatorily mediated by cytochrome P450nor

The involvement of cytochrome P450nor (P450nor) is the most striking feature of the fungal denitrifying system, and has never been shown in bacterial systems. To establish the physiological significance of the P450nor, we constructed and investigated mutants of Fusarium oxysporum that lacked the gene for P450nor. We mutated the gene by targeted integration of a disrupted gene into the chromosome of F. oxysporum. The mutants were shown to contain neither P450nor protein nor nitric oxide (NO) reductase (Nor) activity, implying that they are indeed deficient in P450nor. These mutants had apparently lost the denitrifying activity and failed to evolve nitrous oxide (N₂O) upon incubation under oxygen-limiting conditions in the presence of nitrate. Their mycelia exhibited normal levels of dissimilatory nitrite reductase (Nir) activity and were able to evolve NO under these conditions. The promoter region of the P450nor gene was fused to lacZ and introduced into the wild-type strain of F. oxysporum. The transformed strain produced β-galactosidase under denitrifying conditions as efficiently as the wild type does P450nor. These results represent unequivocal genetic evidence that P450nor is essential for the reduction of NO to N₂O, the last step in denitrification by F. oxysporum. Received: 28 June 1999 / Accepted: 22 December 1999