Enxerto pediculado de omento maior como adjuvante no tratamento de osteomielite de tíbia em cão ˗ relato de caso

RESUMO A osteomielite é um desafio terapêutico em ortopedia, capaz de retardar ou mesmo impedir a consolidação óssea. O omento, há anos, tem sido empregado como alternativa em diferentes procedimentos cirúrgicos, por sua capacidade, entre outras, de angiogênese, sendo aplicado na ortopedia veterinária quando há o risco de não união óssea. Neste caso, um cão Fila Brasileiro foi submetido à realização de enxerto com retalho pediculado de omento maior, após osteomielite resistente presente em osteossíntese de fratura múltipla de tíbia aberta grau II. Durante 16 dias, manteve-se a comunicação do retalho, mas, diante do risco de peritonite, o pedículo foi seccionado. Numa sequência de intervenções cirúrgicas, após 89 dias, houve cicatrização óssea e remissão da osteomielite, mesmo na presença de bactérias multirresistentes. Neste relato, o omento foi efetivo como terapia adjuvante no tratamento da osteomielite e garantiu o retorno da função do membro.

Survivin, a target to modulate the radiosensitivity of Ewing's sarcoma

BACKGROUND AND PURPOSE

Radiotherapy constitutes an essential element in the multimodal therapy of Ewing's sarcoma. Compared to other sarcomas, Ewing tumors normally show a good response to radiotherapy. However, there are consistently tumors with a radioresistant phenotype, and the underlying mechanisms are not known in detail. Here we investigated the association between survivin protein expression and the radiosensitivity of Ewing's sarcoma in vitro.

MATERIAL AND METHODS

An siRNA-based knockdown approach was used to investigate the influence of survivin expression on cell proliferation, double-strand break (DSB) induction and repair, apoptosis and colony-forming ability in four Ewing's sarcoma cell lines with and without irradiation.

RESULTS

Survivin protein and mRNA were upregulated in all cell lines tested in a dose-dependent manner. As a result of survivin knockdown, STA-ET-1 cells showed reduced cell proliferation, an increased number of radiation-induced DSBs, and reduced repair. Apoptosis was increased by knockdown alone and increased further in combination with irradiation. Colony formation was significantly reduced by survivin knockdown in combination with irradiation.

CONCLUSION

Survivin is a radiation-inducible protein in Ewing's sarcoma and its down-regulation sensitizes cells toward irradiation. Survivin knockdown in combination with radiation inhibits cell proliferation, repair, and colony formation significantly and increases apoptosis more than each single treatment alone. This might open new perspectives in the radiation treatment of Ewing's sarcoma.

Requirements of team effectiveness in neurosurgical rehabilitation

The purpose of this article is to stress the importance of working with interdisciplinary teams in neurorehabilitation and describe requirements of team effectiveness. It is not sufficient to focus only on different impairments associated with brain injury and offer individuals a variety of therapy. The essential aspect in neurorehabilitation is the integration of disciplines and consistent goal setting to regard individual patient's needs. Interdisciplinary teams benefit from a leader qualified for neuroscience, neurorehabilitation, clinical neuropsychology and psychotherapy. A good structural organization of the team, notice of basic communication rules, understanding typical group dynamics and stressors of interdisciplinary teams, conflict management and a definite decision making increase productive interdisciplinary working and enable the team to continue to mature. Further empirical research is necessary to support the effectiveness of interdisciplinary teams as an important variable in the evaluation of rehabilitation outcome and quality control.

Isolation and sequence analysis of three cloned cDNAs for rabbit liver proteins that are related to rabbit cytochrome P-450 (form 2), the major phenobarbital-inducible form

We have isolated from rabbit liver three cDNA clones of 1400-1800 base pairs that hybridize selectively to RNA from animals treated with phenobarbital. The nucleotide sequences of the cDNAs have been determined. In the protein coding region the nucleotide sequences of two of the cDNAs are 88% homologous, and the third cDNA is about 72-74% homologous to the other two. All three are 55-60% homologous to rat liver cytochrome P-450b cDNA. The amino acid sequences derived from the cDNA sequences are about 50% homologous to those of rat liver cytochrome P-450b and rabbit liver cytochrome P-450 (form 2). The degree of homology differs substantially in different regions of the protein. The hydrophobicity profiles of these five mammalian cytochromes P-450 are very similar and contain up to eight regions of hydrophobicity that are long enough to span a membrane. These results indicate that these three cDNAs code for rabbit liver cytochromes P-450 which are different from any rabbit liver cytochrome P-450 for which amino acid sequence information is published. These cDNAs are part of a family of genes that are related to rabbit liver cytochrome P-450 (form 2) and rat liver cytochrome P-450b which are the major phenobarbital-inducible forms. The divergence of amino acid sequence between the rat and rabbit forms and the divergence of nucleotide sequences of silent sites in the two most closely related rabbit forms suggest that cytochromes P-450 have a relatively high rate of amino acid divergence compared to many other vertebrate proteins.

The juxtamembrane sequence of cytochrome P-450 2C1 contains an endoplasmic reticulum retention signal

The N-terminal signal anchor of cytochrome P-450 2C1 mediates retention in the endoplasmic reticulum (ER) membrane of several reporter proteins. The same sequence fused to the C terminus of the extracellular domain of the epidermal growth factor receptor permits transport of the chimeric protein to the plasma membrane. In the N-terminal position, the ER retention function of this signal depends on the polarity of the hydrophobic domain and the sequence KQS in the short hydrophilic linker immediately following the transmembrane domain. To determine what properties are required for the ER retention function of the signal anchor in a position other than the N terminus, the effect of mutations in the linker and hydrophobic domains on subcellular localization in COS1 cells of chimeric proteins with the P-450 signal anchor in an internal or C-terminal position was analyzed. For the C-terminal position, the signal anchor was fused to the end of the luminal domain of epidermal growth factor receptor, and green fluorescent protein was additionally fused at the C terminus of the signal anchor for the internal position. In these chimeras, the ER retention function of the signal anchor was rescued by deletion of three leucines at the C-terminal side of its hydrophobic domain; however, deletion of three valines from the N-terminal side did not affect transport to the cell surface. ER retention of the C-terminal deletion mutants was eliminated by substitution of alanines for glutamine and serine in the linker sequence. These data are consistent with a model in which the position of the linker sequence at the membrane surface, which is critical for ER retention, is dependent on the transmembrane domain.

Gastric wall elasticity assessed by dynamic holographic endoscopy: ex vivo investigations in the porcine stomach

BACKGROUND

Holographic interferometry is based on the superimposition of the holograms of different motional states of an object on a single holographic storage medium. It has been used to detect structural changes in prosthetic heart valves. The combination of holographic interferometry and endoscopic imaging were applied to assess disturbances of porcine stomach wall elasticity.

METHODS

By connecting an electronic speckle pattern interferometry (ESPI) camera system (light source: continuous wave argon-ion laser, lambda = 514.5 nm) to different types of endoscopes, ex vivo experiments were performed on porcine stomachs to detect areas characterized by altered tissue elasticity. With linkage of the endoscopic ESPI camera complex to a fast image processing system, the method of double pulse exposure image subtraction was applied at a video frame rate of 12.5 Hz.

RESULTS

The speckle correlation patterns resulting from gentle gastric wall deformation were analyzed in a series of experiments in 16 porcine stomachs. Interferograms of gastric wall areas without structural abnormalities exhibited concentric fringes, whereas fringe patterns corresponding to areas of reduced tissue elasticity were characterized by parallel lines.

CONCLUSION

Applying the nondestructive method of dynamic holographic endoscopy, abnormalities of the gastric wall leading to diminished tissue elasticity can be distinguished reliably from surrounding healthy tissue.

N-terminal deletions and His-tag fusions dramatically affect expression of cytochrome p450 2C2 in bacteria

The expression of mutants with deletions in the N-terminal signal-anchor sequence of cytochrome P450 2C2 and His-tag fusions was examined in Escherichia coli to determine the influence of N-terminal sequences on expression of the protein. Two mutants predicted to be translocated across the membrane inhibited bacterial growth. In other mutants, deletion of the N-terminal transmembrane domain (residues 2-20) reduced expression of functional P450 by about 75% and further deletion of the following linker sequence (residues 21-27) resulted in a modest further decrease. Expression of the mutant with residues 2-27 deleted contrasts with the lack of expression of functional protein if only the linker was deleted, which suggests that the linker sequence is critical for expression only if the protein is inserted into the membrane by the transmembrane domain. Fusion proteins of green fluorescent protein with full-length P450 2C2 and 2C2(Delta2-20) were predominantly membrane-associated in vivo as determined by fluorescence microscopy. Subcellular fractionation of bacteria expressing these proteins and extraction of the proteins from the membrane by high salt or alkaline buffer demonstrated that P450 2C2 was an integral membrane protein while 2C2(Delta2-20) was a peripheral membrane protein that associated with the membrane mainly by hydrophobic interactions. Residues 1-27 of P450 2C2 fused to green fluorescent protein resulted in a redistribution of fluorescence from cytosol to membrane, which, with the deletion studies, indicates that the P450 signal-anchor is both necessary and sufficient for normal membrane targeting and is the sole transmembrane domain of cytochrome P450 2C2 in bacteria. Addition of a His-tag at the N-terminus completely restored wild-type expression levels to the 2C2(Delta2-20) mutants in bacteria. In insect cells, functional 2C2(Delta2-20) was not expressed but an N-terminal His-tag also restored full expression. The increase in expression may be related to decreased association with the membrane mediated by the His-tag.

Functional analysis of the phenobarbital-responsive unit in rat CYP2B211Abbreviations: P450, cytochrome P450; PB, phenobarbital; CYP, P450 gene; NR, nuclear receptor; NF-1, nuclear factor-1; GRE, glucocorticoid response element; CAR, constitutive androgen receptor; RXR, retinoid X receptor; PBRU, PB response element

An 163-bp fragment of the rat cytochrome P450 gene, CYP2B2 has been shown to contain sequences that mediate phenobarbital (PB) responsiveness of this gene. In studies on this rat gene and the orthologous mouse gene, Cyp2b10, the minimal fragment required for near full PB responsiveness has varied from about 50 to 80 bp depending on the gene used and the number of copies of the PB responsive sequences assessed. Since there is a single copy of the CYP genes in the genome, we have evaluated deletion and block mutations across an 84-bp region of the PB responsive unit (PBRU), by in situ transfection in rat liver using single copies of the PBRU sequences. From the 5' end, deletions to -2243 retained more than 50% responsiveness to PB compared to the 163-bp fragment. The fragment -2237 to -2155 retained less than 20% responsiveness even though it contained the nuclear receptor (NR)-1, NR-2, and NF-1 motifs which are present in the core of the PBRU. From the 3' end, deletions from -2170 to -2194 eliminated PB responsiveness indicating that the 74-bp sequence from -2243 to -2170 is able to mediate full PB responsiveness. Block mutations within the NR-1 and NF-1 regions reduced responsiveness most dramatically, but did not abolish it, and mutations 3' of the NF-1 site modestly reduced responsiveness. Protein binding was not affected by mutations in the NR-1 region as assessed by DNase I footprinting in vitro but mutations within the NR-2 region reduced binding to the NF-1 site. Mutations of the 5' half or the 3' half of the bipartite NF-1 site, resulted in loss of protection of the NF-1 site and new footprints to the 3' or 5' side, respectively, of the NF-1 site. These results indicate that sequences in addition to the NR-1 and -2 and the NF-1 sites are required for full responsiveness to PB and suggest that proteins which bind to these sites may interact.

Holliday junction resolving enzymes of archaeal viruses SIRV1 and SIRV2

In the final stages of genetic recombination, Holliday junction resolving enzymes transform the four-way DNA intermediate into two duplex DNA molecules by introducing pairs of staggered nicks flanking the junction. This fundamental process is apparently common to cells from all three domains of life. Two cellular resolving enzymes from extremely thermophilic representatives of both kingdoms of the domain Archaea, the euryarchaeon Pyrococcus furiosus and the crenarchaeon Sulfolobus solfataricus, have been described recently. Here we report for the first time the isolation, purification and characterization of Holliday junction cleaving enzymes (Hjc) from two archaeal viruses. Both viruses, SIRV1 and SIRV2, infect Sulfolobus islandicus. Their Hjcs both consist of 121 amino acid residues (aa) differing only by 18 aa. Both proteins bind selectively to synthetic Holliday-structure analogues with an apparent dissociation constant of 25 nM. In the presence of Mg(2+) the enzymes produce identical cleavage patterns near the junction. While S. islandicus shows optimal growth at about 80 degrees C, the nucleolytic activities of recombinant SIRV2 Hjc was highest between 45 degrees C and 70 degrees C. Based on their specificity for four-way DNA structures the enzymes may play a general role in genetic recombination, DNA repair and the resolution of replicative intermediates.

Conformational flexibility in T4 endonuclease VII revealed by crystallography: implications for substrate binding and cleavage

The structure of the N62D mutant of the junction-resolving endonuclease VII (EndoVII) from phage T4 has been refined at 1.3 A, and a second wild-type crystal form solved and refined at 2.8 A resolution. Comparison of the mutant with the wild-type protein structure in two different crystal environments reveals considerable conformational flexibility at the dimer level affecting the substrate-binding cleft, the dimerization interface and the orientation of the C-terminal domains. The opening of the DNA-binding cleft, the orientation of the C-terminal domains relative to the central dimerization domain as well as the relative positioning of helices in the dimerization interface appear to be sensitive to the crystal packing environment. The highly unexpected rearrangement within the extended hydrophobic interface does change the contact surface area but keeps the number of hydrophobic contacts about the same and will therefore not require significant energy input. The conformational flexibility most likely is of functional significance for the broad substrate specificity of EndoVII. Binding of sulphate ions in the mutant structure and their positions relative to the active-site metal ions and residues known to be essential for catalysis allows us to propose a possible catalytic mechanism. A comparison with the active-site geometries of other magnesium-dependent nucleases, among them the homing endonuclease I-PpoI and Serratia endonuclease, shows common features, suggesting related catalytic mechanisms.

Chromatin assembly enhances binding to the CYP2B1 phenobarbital-responsive unit (PBRU) of nuclear factor-1, which binds simultaneously with constitutive androstane receptor (CAR)/retinoid X receptor (RXR) and enhances CAR/RXR-mediated activation of the PBRU

Phenobarbital induction of CYP2B genes is mediated by a complex phenobarbital-responsive enhancer (PBRU), which contains a binding site for nuclear factor-1 (NF-1) flanked by two DR-4 nuclear receptor (NR) binding sites for a heterodimer of constitutive androstane receptor (CAR) and retinoid X receptor (RXR). To examine potential interactions between NF-1 and CAR/RXR, binding of purified recombinant proteins to DNA, or to chromatin assembled using Drosophila embryo extract, was examined. NF-1 and CAR/RXR bound simultaneously and independently to the overlapping NF-1 and NR-1 sites; binding of CAR/RXR to the NR-2 site was modestly increased by NF-1 binding; and CAR/RXR bound to a new site in the PBRU region, designated NR-3. Assembly of plasmid DNA into chromatin using Drosophila extract resulted in linearly phased nucleosomes in the PBRU region. The apparent binding affinity of NF-1 was increased by about 10-fold in assembled chromatin compared with DNA, whereas CAR/RXR binding was decreased. As observed for DNA, however, simultaneous, largely independent, binding to the NF-1 and NR sites was observed. CAR-mediated transactivation of the PBRU in cultured cells of hepatic origin was inhibited by mutations in the NF-1 site, and overexpression of NF-1 increased CAR transactivation in HepG2 cells. These studies demonstrate that NF-1 and CAR/RXR can both bind to the PBRU at the same time and that chromatin assembly increases NF-1 binding, which is consistent with previous in vivo footprinting studies in which the NF-1 site was occupied in untreated animals and the NF-1 and flanking NR sites were occupied after phenobarbital treatment. CAR-mediated trans-activation of the PBRU was increased by NF-1, analogous to NF-1 effects on phenobarbital induction in previous transient transfection studies and consistent with mediation of phenobarbital induction by CAR.

Analyses of spontaneous mutations of cloned gene 49 of phage T4

Holliday structure resolving enzyme endonuclease VII (endo VII) of phage T4 is highly toxic for E. coli when expressed outside of the phage infection environment. As a consequence, plasmids with a mutated gene 49, the gene which encodes for endo VII, can be easily isolated and characterised. We have isolated and characterised 400 survivors from independent transformations with a plasmid carrying gene 49 under the control of the T7 promoter. The majority had mutated gene 49 by IS10 insertions which almost exclusively mapped to a distinct site. When this site was mutated other insertion sites were observed as well as an increase in other mutational events including large deletions. Neither of the observed insertion sites mapped matched the consensus IS10 sequence completely. Additionally when the level of expression of gene 49 was altered the distribution of mutations was changed suggesting that other elements apart from the target sequence are necessary for determining IS10 insertion. The expression of gene 49 in E. coli provides a particularly useful tool for the analysis of mutational events.

Endoscopic double-pulse electronic-speckle-pattern interferometer for technical and medical intracavity inspection

An endoscope electronic-speckle-pattern interferometer (ESPI) camera system is presented that can be applied to examinations of technical objects as well as for in vitro and in vivo minimal invasive medical diagnostics. Integration of optical fibers for the guidance of a cw-laser beam and an endoscopic imaging system yield a compact ESPI system that opens up new possibilities for highly sensitive interferometric intracavity inspection under handheld conditions. A CCD camera in combination with a fast frame-grabber system allows dynamic image subtractions at a frequency rate of as much as 25 Hz with high fringe contrast. Results from investigations of technical objects and biological objects in vitro and in vivo are obtained. In endoscopic minimal invasive therapy this method could substitute for the missing operator's tactile contact with the treated tissue by replacing it with visual information (endoscopic taction).

Endoplasmic reticulum retention determinants in the transmembrane and linker domains of cytochrome P450 2C1

The cytochrome P450 2C1 N-terminal signal anchor sequence mediates direct retention of the protein in the endoplasmic reticulum and consists of a hydrophobic transmembrane domain, residues 3-20, followed by a hydrophilic linker, residues 21-28. Fusions of the N-terminal 21 or 28 amino acids of P450 2C1 to green fluorescent protein resulted in endoplasmic reticulum localization of the chimera in transfected cells. Disruption of microtubules by nocodazole treatment resulted in redistribution into a punctate pattern for the 1-21, but not for the 1-28, chimera indicating that the linker was preventing transport from the endoplasmic reticulum but was not required for retrieval to the endoplasmic reticulum from the pre-Golgi compartment. In the 1-28 chimera, mutations of residues 21-23 (KQS) in the linker resulted in redistribution of the chimera after nocodazole treatment. Mutations in the transmembrane domain affected both direct retention in the endoplasmic reticulum and retrieval from the pre-Golgi compartment, and although structural requirements for each process are distinct, in both cases the arrangement of amino acids and distribution of hydrophobicity are critical. In contrast, the linker region exhibits a sequence-specific requirement for direct retention in the endoplasmic reticulum.

Torsional control of double-stranded DNA branch migration

DNA branched junctions are analogues of Holliday junction recombination intermediates. Partially mobile junctions contain a limited amount of homology flanking the branch point. A partially mobile DNA branched junction has been incorporated into a synthetic double-stranded circular DNA molecule. The junction is flanked by four homologous nucleotide pairs, so that there are five possible locations for the branch point. Two opposite arms of the branched junction are joined to form the circular molecule, which contains 262 nucleotides to the base of the junction. This molecule represents a system whereby torque applied to the circular molecule can have an impact on the junction, by relocating its branch point. Ligation of the molecule produces two topoisomers; about 87% of the product is a relaxed molecule, and the rest is a molecule with one positive supercoil. The position of the branch point is assayed by cleaving the molecule with endonuclease VII. We find that the major site of the branch point in the relaxed topoisomer is at the maximally extruded position in the relaxed molecule. Upon the addition of ethidium, the major site of the branch point migrates to the minimally extruded position.

[Neuropsychological fields in early neurotrauma rehabilitation]

It meanwhile is commonly accepted that early onset of specific rehabilitation intervention in traumatic brain injured patients will enhance the recovery of brain function. The integration of neuropsychology in the early treatment of traumatic brain injury can mainly be ascribed to the increasing recognition that cognitive, personality and emotional deficits have been the most devasting longterm problems faced by patients and their families. The aim of our paper is to illustrate the role of neuropsychology in the early stage of rehabilitation. Neuropsychological therapy and the application of appropriate tests depend on the level of consciousness and the extent of behavioural problems. Observation, cognitive screening tests and the use of valid neuropsychological tests make up the main approaches. Our rehabilitation program includes measures of sensory and cognitive stimulation. Improvement of attention and stimulation of cognitive functions are one of the most important aims of early neuropsychological therapy. We choose tasks which require automatic information processing, the retrieval of well established knowledge and implicit learning. Appropriate tests and the development of neuropsychological treatment programmes represent an important means of maximising the patient's capacity to benefit from early rehabilitation.

Tissue-specific chromatin structure of the phenobarbital-responsive unit and proximal promoter of CYP2B1/2 and modulation by phenobarbital

Phenobarbital induction of transcription of CYP2B genes is mediated by an enhancer, termed a phenobarbital responsive unit (PBRU), approximately 2000 bp 5' of the transcription start site. To further delineate the mechanism of phenobarbital induction, protein binding in native chromatin and the nucleosomal structure of the PBRU and proximal promoter were examined in liver and kidney, in which the CYP2B1/2 genes are expressed and not expressed, respectively. Protein binding to the PBRU in kidney chromatin was not detected even though in vitro DNase I footprints were not detectably different with nuclear extracts from liver and kidney. Likewise, protein binding to regulatory motifs was not detected in the proximal promoter region in kidney chromatin. In liver chromatin, however, DNase I hypersensitivity and partial protection of the regulatory motifs from DNase I digestion or reaction with dimethyl sulfate was observed and phenobarbital treatment increased the hypersensitivity but only modestly affected protection. Low resolution Southern analysis of micrococcal nuclease-digested chromatin from untreated rats revealed micrococcal nuclease hypersensitive regions in the proximal promoter and PBRU regions in liver, but not in kidney. Phenobarbital treatment increased hyper-sensitivity in liver in both regions. Micrococcal nuclease hypersensitivity in the PBRU was largely restricted to a linker region between phased nucleosomes while in the proximal promoter hypersensitivity extended over approximately 200 bp suggesting disruption of a nucleosome in this region. These data indicate that in liver phenobarbital treatment substantially alters protein binding to regulatory motifs in the PBRU, while not greatly affecting such binding in the proximal promoter, and substantially alters chromatin structure in both regions, presumably as a result of chromatin modifying factors recruited to the PBRU. In the kidney, chromatin is probably in a closed conformation that prevents binding of regulatory factors.

Cytochromes P450 2C1/2 and P450 2E1 are retained in the endoplasmic reticulum membrane by different mechanisms

Cytochrome P450 (P450) 2C1/2 contains redundant endoplasmic reticulum (ER) retention signals and is excluded from the recycling pathway. Other P450s, such as P450 2E1, have been detected in the plasma membrane and Golgi apparatus. To examine whether the mechanisms of ER retention might differ for P450 2C1/2 and P450 2E1, chimeras of green flourescent protein and the full-length proteins, N-terminal signal/anchor sequences, or the cytoplasmic catalytic domains from these proteins have been expressed in COS1 cells. Chimeras with either the N-terminal signal/anchor sequence or the cytoplasmic domain of P450 2C1/2 were retained in the ER and the distribution was not altered by treatment with nocodazole. A chimera with full-length P450 2E1 was located in the ER, but in contrast to P450 2C1/2, treatment with nocodazole resulted in redistribution to a vesicular pattern, which suggested that this protein was retained in the ER by a retrieval mechanism. In support of this possibility, the P450 2E1 chimera, but not the P450 2C1/2 chimera, was included in transport vesicles generated in an in vitro budding assay. A chimera with only the N-terminal signal/anchor sequence of P450 2E1 fused to green fluorescent protein was located in the ER and nocodazole treatment altered its distribution, whereas a chimera with only the cytoplasmic domain of P450 2E1 was not efficiently retained in the ER and accumulated primarily in the Golgi region. These results demonstrate that the mechanisms for retention in the ER of two closely related members of the P450 superfamily are different and that the N-terminal signal/anchor sequence contains the dominant retention signal.

No braiding of Holliday junctions in positively supercoiled DNA molecules

The Holliday junction is a prominent intermediate in genetic recombination that consists of four double helical arms of DNA flanking a branch point. Under many conditions, the Holliday junction arranges its arms into two stacked domains that can be oriented so that genetic markers are parallel or antiparallel. In this arrangement, two strands retain a helical conformation, and the other two strands effect the crossover between helical domains. The products of recombination are altered by a crossover isomerization event, which switches the strands fulfilling these two roles. It appears that effecting this switch from the parallel conformation by the simplest mechanism results in braiding the crossover strands at the branch point. In previous work we showed by topological means that a short, parallel, DNA double crossover molecule with closed ends did not braid its branch point; however, that molecule was too short to adopt the necessary positively supercoiled topology. Here, we have addressed the same problem using a larger molecule of the same type. We have constructed a parallel DNA double crossover molecule with closed ends, containing 14 double helical turns in each helix between its crossover points. We have prepared this molecule in a relaxed form by simple ligation and in a positively supercoiled form by ligation in the presence of netropsin. The positively supercoiled molecule is of the right topology to accommodate braiding. We have compared the relaxed and supercoiled versions for their responses to probes that include hydroxyl radicals, KMnO4, the junction resolvases endonuclease VII and RuvC, and RuvC activation of KMNO4 sensitivity. In no case did we find evidence for a braid at the crossover point. We conclude that Holliday junctions do not braid at their branch points, and that the topological problem created by crossover isomerization in the parallel conformation is likely to be solved by distributing the stress over the helices that flank the branch point.

Substitutions in the C-terminal portion of the catalytic domain partially reverse assembly defects introduced by mutations in the N-terminal linker sequence of cytochrome P450 2C2

Mutations in a 7-amino acid linker segment, immediately following the N-terminal signal anchor sequence of cytochrome P450 2C2, have been shown to affect proper assembly of hemoprotein and decrease activity of the mutants expressed in COS cells. In contrast, C2pmBalC1, in which cytochrome P450 2C1 residues were substituted for those of cytochrome P450 2C2 in the C-terminal region, exhibited increased activity when expressed in COS-1 cells. To examine further the basis for the increased activity of C2pmBalC1 in COS-1 cells, the protein was expressed in insect cells and Escherichia coli. The amounts of the functional P450 species of C2pmBalC1 expressed in these systems and the ratios of P450 to P420 were greater than those of cytochrome P450 2C2, indicating that more efficient assembly underlies the increased activity of C2pmBalC1. To determine whether the C-terminal substitutions could compensate for the decreased assembly mediated by the N-terminal linker mutations, the linker mutations were introduced into C2pmBalC1. If all 7 amino acids in the linker were deleted, no enzymatically active cytochrome P450 2C2 or C2pmBalC1 was detected in COS-1, insect, or bacterial cells expressing the mutants. The mutant C2A2, in which two alanines were substituted for the linker, had no detectable laurate hydroxylase activity in COS-1 cells, and minor amounts of hemoprotein for this mutant were expressed in E. coli and insect cells. In contrast, the same mutation in C2pmBalC1 reduced activity only 50% in COS-1 cells and markedly elevated levels of P450 expression in bacteria and insect cells. The A2 mutation did not affect the enzymatic activity of either cytochrome P450 2C2 or C2pmBalC1 assayed in whole cell lysates of insect cells but reduced the activity of partially purified enzymes assayed in a reconstituted assay system. These findings indicate that mutations introduced into the C-terminal region of P450 2C2 can facilitate assembly of the proteins and partially reverse the decreased assembly resulting from the N-terminal mutations.

Enzymatic mutation detection: enrichment of heteroduplexes from hybrid DNA mixtures by cleavage-deficient GST-tagged endonuclease VII

A method for the enrichment of heteroduplex DNAs from hybrid DNA mixtures by endonuclease VII is reported. The procedure is based on the ability of a GST-fused cleavage-deficient mutant endonuclease VII (EVII-N62D(GST)) to bind to mismatching nucleotides in heteroduplex DNAs identical to the wild-type enzyme. The GST tag was used for stable immobilisation of the protein to Glutathione Sepharose 4B. This enables the material to withstand the repeated rounds of binding steps required for enrichment of heteroduplex molecules from appropriate samples.

X-ray structure of T4 endonuclease VII: a DNA junction resolvase with a novel fold and unusual domain-swapped dimer architecture

Phage T4 endonuclease VII (Endo VII), the first enzyme shown to resolve Holliday junctions, recognizes a broad spectrum of DNA substrates ranging from branched DNAs to single base mismatches. We have determined the crystal structures of the Ca2+-bound wild-type and the inactive N62D mutant enzymes at 2.4 and 2.1 A, respectively. The Endo VII monomers form an elongated, highly intertwined molecular dimer exhibiting extreme domain swapping. The major dimerization elements are two pairs of antiparallel helices forming a novel 'four-helix cross' motif. The unique monomer fold, almost completely lacking beta-sheet structure and containing a zinc ion tetrahedrally coordinated to four cysteines, does not resemble any of the known junction-resolving enzymes, including the Escherichia coli RuvC and lambda integrase-type recombinases. The S-shaped dimer has two 'binding bays' separated by approximately 25 A which are lined by positively charged residues and contain near their base residues known to be essential for activity. These include Asp40 and Asn62, which function as ligands for the bound calcium ions. A pronounced bipolar charge distribution suggests that branched DNA substrates bind to the positively charged face with the scissile phosphates located near the divalent cations. A model for the complex with a four-way DNA junction is presented.

Association of holliday-structure resolving endonuclease VII with gp20 from the packaging machine of phage T4

Endonuclease VII (endo VII) is the product of gene 49 (gp49) of bacteriophage T4. It is a Holliday-structure resolvase (X-solvase) responsible for clearing branched replicative DNA prior to packaging. Consequently, mutations in gene 49 are unable to fill heads to completion because unresolved branches stop translocation of DNA. A likely association of gp49 with heads or proheads, however, could not be shown in the past. We have investigated whether gp49 could be part of the transiently assembled packaging machine (the "packasome") located at the base of proheads. Using purified proteins gpl6, gpl7 and gp20, which are constituents of the packasome, we found that gp49 binds tightly to gp20 and does not bind to gpl6 or gpl7. Quantification revealed that one dimer of gp49 binds one monomer of gp20. Notably, dimerisation of gp49 was an essential prerequisite for complex formation with gp20, and the dimerisation-deficient point mutation His-EVII-W87R showed only residual affinity to gp20. Furthermore, truncated peptides of gp49 deficient in dimer formation to various degrees were found to be impaired in binding to gp20. In contrast, the cleavage-deficient mutation EVII-N62D bound normally to gp20. The cruciform DNA (cf-DNA) resolving activity typical of endo VII is maintained in gp20-gp49 complexes. Furthermore, the complexes bind cf-DNA in the absence of Mg2+ as demonstrated by electromobility shift assays. The binding of the complexes to cf-DNA occurs via gp49, since gp20 alone does not bind cf-DNA. In conclusion, these findings are consistent with a model in which gp49 is an integral part of the packaging machine of phage T4.

Mobility of cytochrome P450 in the endoplasmic reticulum membrane

Cytochrome P450 2C2 is a resident endoplasmic reticulum (ER) membrane protein that is excluded from the recycling pathway and contains redundant retention functions in its N-terminal transmembrane signal/anchor sequence and its large, cytoplasmic domain. Unlike some ER resident proteins, cytochrome P450 2C2 does not contain any known retention/retrieval signals. One hypothesis to explain exclusion of resident ER proteins from the transport pathway is the formation of networks by interaction with other proteins that immobilize the proteins and are incompatible with packaging into the transport vesicles. To determine the mobility of cytochrome P450 in the ER membrane, chimeric proteins of either cytochrome P450 2C2, its catalytic domain, or the cytochrome P450 2C1 N-terminal signal/anchor sequence fused to green fluorescent protein (GFP) were expressed in transiently transfected COS1 cells. The laurate hydroxylase activities of cytochrome P450 2C2 or the catalytic domain with GFP fused to the C terminus were similar to the native enzyme. The mobilities of the proteins in the membrane were determined by recovery of fluorescence after photobleaching. Diffusion coefficients for all P450 chimeras were similar, ranging from 2.6 to 6.2 x 10(-10) cm2/s. A coefficient only slightly larger (7.1 x 10(-10) cm2/s) was determined for a GFP chimera that contained a C-terminal dilysine ER retention signal and entered the recycling pathway. These data indicate that exclusion of cytochrome P450 from the recycling pathway is not mediated by immobilization in large protein complexes.

[Juvenile neuronal ceroid lipofuscinosis (Spielmeyer-Vogt disease)]

BACKGROUND

The neuronal ceroid-lipofuscinosis (NCL) belongs to progressive neurodegenerative disorders of childhood with both ophthalmologic and neurologic symptoms. In the most common type in Germany, the juvenile type, the ophthalmological examination is essential for an early diagnosis.

PATIENT

A 5-year-old boy had exhibited a loss of visual acuity, visual field and colour perception in his pre-school age. His clinical features and electrophysiologic data are presented. The final diagnostic clues were drawn from the neuropediatric and cytologic examinations.

RESULTS

This patient shows the typical clinical feature of the juvenile NCL with a relatively rapid visual loss with bull's eye maculopathy in the pre-school- to early school age. His electroretinogram was abolished, and his EEG showed pathologic results. The diagnosis could be established by electron microscopy of his lymphocytes. Epilepsy and intellectual defects are expected to set in only few years later.

CONCLUSIONS

Although there is no therapy, the ophthalmologist should be aware of this rare entity because prognostic counselling, social help and perhaps genetic counselling could be offered to the families. In many cases, a prenatal diagnosis is possible.

Binding of endonuclease VII to cruciform DNA. Visualization in the electron microscope

The binding of Holliday structure resolving endonuclease VII to cruciform DNA was studied in the electron microscope. The protein was found to bind either to the junction or to one of the arms or an end of one of the arms of the construct. The amount of bound protein was determined by measuring the size of the complexes. On average, one complex containing three dimers was found per one molecule of cruciform DNA.

An apyrimidinic site kinks DNA and triggers incision by endonuclease VII of phage T4

Apurinic/apyrimidinic lesions (AP-sites) occur frequently in DNA, generated by physically and chemically induced or spontaneous loss of bases. Repair mechanisms have evolved in organisms to deal efficiently with AP-sites by first incising the DNA at the lesion, followed by excision and resynthesis of the damaged strand. Here we report that endonuclease VII (endo VII) of phage T4, which was originally classified as a debranching and Holliday structure resolving enzyme, also recognizes AP-sites with high efficiency. The enzyme cleaves both strands of double-stranded DNA in a stepwise fashion a few nucleotides 3' of the lesion. In a search for a recognition signal shared by all known endo VII substrates, kinking of DNA has earlier been suggested as such a signal. In support of this hypothesis, we demonstrate here that AP-sites induce distinct kinks in synthetic oligonucleotides allowing efficient intramolecular ring closure by ligation.

Regulation of cytochrome P450 gene transcription by phenobarbital

The ability of phenobarbital to induce levels of drug metabolism in mammals has been known for over 40 years. However, the molecular mechanisms underlying increased expression of the genes of the key enzyme in drug metabolism, cytochrome P450, have not been elucidated, primarily because in vitro model systems in which the induction could be studied were not available. Transfected primary cultured hepatocytes, transfection of liver in situ, and transgenic mice now provide suitable models for phenobarbital induction. In this review, progress toward understanding the mechanism of phenobarbital induction of gene expression is discussed with an emphasis on the mammalian genes, CYP2B1, CYP2B2, and Cyp2b10, which are most highly inducible by phenobarbital. Barbiturate induction of P450s in Bacillus megaterium, which is the system best understood, and its relevance to mammalian mechanisms of induction are also discussed. In B. megaterium, the binding of a repressor to several motifs is reversed by direct effects of barbiturates and by induction of positively acting factors. One of the repressor binding sites, the barbie box, is present in many mammalian phenobarbital-inducible genes, including the promimal promoter regions of CYP2B1, CYP2B2, and Cyp2B10. In the mammalian P450 genes, evidence has been proposed for phenobarbital-regulated elements both in the proximal promoter region and in a distal enhancer region. The role of the proximal region is controversial. A positively acting element that overlaps the barbie box sequence and a negative element have been proposed to mediate induction of CYP2B1/2, based primarily on protein binding and cell-free transcription assays. In contrast, other investigators have not found differences in phenobarbital-dependent protein binding in the proximal promoter region nor mediation of phenobarbital induction by this region. A distal gene fragment, at about -2000 kb in CYP2B1, CYP2B2, and Cyp2b10, has been shown to be a phenobarbital-responsive enhancer independent of proximal promoter elements. This fragment contains several binding sites for proteins and several functional elements, including an NF-1 site, and, therefore, has been designated as a phenobarbital-responsive unit. Possible models are presented in which phenobarbital treatment induces altered chromatin structure, which allows the binding of positively acting factors, or activates factors already bound, to the distal enhancer and the proximal promoter.

Structural maintenance of chromosomes protein C-terminal domains bind preferentially to DNA with secondary structure

Structural maintenance of chromosomes (SMC) proteins interact with DNA in chromosome condensation, sister chromatid cohesion, DNA recombination, and gene dosage compensation. How individual SMC proteins and their functional domains bind DNA has not been described. We demonstrate the ability of the C-terminal domains of Saccharomyces cerevisiae SMC1 and SMC2 proteins, representing two major subfamilies with different functions, to bind DNA in an ATP-independent manner. Three levels of DNA binding specificity were observed: 1) a >100-fold preference for double-stranded versus single-stranded DNA; 2) a high affinity for DNA fragments able to form secondary structures and for synthetic cruciform DNA molecules; and 3) a strong preference for AT-rich DNA fragments of particular types. These include fragments from the scaffold-associated regions, and an alternating poly(dA-dT)-poly(dT-dA) synthetic polymer, as opposed to a variety of other polymers. Reannealing of complementary DNA strands is also promoted primarily by the C-terminal domains. Consistent with their in vitro DNA binding activity, we show that overexpression of the SMC C termini increases plasmid loss without altering viability or cell cycle progression.

Endonuclease VII has two DNA-binding sites each composed from one N- and one C-terminus provided by different subunits of the protein dimer

Endonuclease VII (endo VII) is a Holliday structure-resolving enzyme of bacteriophage T4. Its activity depends on dimerization, DNA binding and hydrolysis of two phosphodiester bonds flanking the Holliday junction. We analysed the DNA-binding activity of truncated monomeric and covalently linked dimeric endo VII proteins. We show that both ends of endo VII are involved in DNA binding. In particular, the C-terminus of one subunit interacts with the N-terminus of the other subunit, constituting one DNA-binding site; the other two termini form the second binding site of the dimer. One binding site is sufficient to bind cruciform DNA. The concerted mechanism involving termini from different subunits ensures that only dimers bind to Holliday structures, thus providing two catalytic centres which introduce two cleavages in opposite strands. This is a precondition for precise resolution of Holliday structures.

Localization and characterization of the dimerization domain of holliday structure resolving endonuclease VII of phage T4

Endonuclease VII (Endo VII) is a Holliday structure resolving enzyme of bacteriophage T4. Its nucleolytic activity depends on subactivities, which in order of execution are: (i) dimerization, (ii) binding to DNA, (iii) and cleavage of DNA. In an effort to assign these subfunctions to the primary sequence of the protein, a series of spontaneous point mutations deficient in DNA cleavage was isolated. Some of these mutations affected the dimerization of Endo VII. Compared with wild-type protein, which dimerizes completely in solution, more than 95% of one of the mutant proteins (W87R) remained in the monomeric state. Only the dimeric fraction of this protein bound to DNA. The dimerization domain of Endo VII was mapped by truncating the gene from both ends and analysing the dimerization ability of the purified peptides by crosslinking with glutaraldehyde. The dimerization domain was thus determined to reside between amino acid residues 55 and 105. Computer analyses predicted two alpha-helices (H2 and H3) in this section of the protein. As demonstrated by heterodimer formation, two copies of helix H3, but only one copy of helix H2, are required for dimerization. Helical wheel analyses revealed that both helices expose a hydrophobic face along their axes, suggesting that hydrophobic interaction between helices H3 mediate formation of Endo VII dimers, while helices H2 stabilize them.

Enzymatic mutation detection. Phosphate ions increase incision efficiency of endonuclease VII at a variety of damage sites in DNA

The ability of endonuclease VII (endo VII) to cleave at mispairings in double-stranded DNA has recently been used for enzymatic mutation detection (EMD) [R. Youil, B.W. Kemper, R.G.H. Cotton, Proc. Natl. Acad. Sci. USA 92 (1995) 87-91]. The method is based on mapping cleavages in heteroduplex DNAs obtained from mutant and wildtype sequences. Despite the capability of endo VII to cleave at all possible mispairings, relative cleavage efficiencies vary considerably for individual mismatches and may escape detection if located in an unfavorable sequence surrounding. We report here improved reaction conditions which can increase the selectivity of the enzyme for mismatches up to 500-fold, as demonstrated with a mutation in a 247 nt long fragment from exon 7 of human gene p53. The new conditions involve replacement of Tris/HCl buffer by phosphate buffer and change from pH 8.0 to 6.5. Various concentrations of phosphate ions should be tried in the assay to meet individual requirements of the substrate.

Nuclear factor-1 motif and redundant regulatory elements comprise phenobarbital-responsive enhancer in CYP2B1/2

Although the induction of drug-metabolizing systems by phenobarbital has been recognized for about 40 years, the mechanism by which cytochrome P450 gene expression is increased is still not well understood. A 163-bp fragment at about -2.2 Kb in CYP2B2 has been shown to mediate phenobarbital induction in primary rat hepatocytes (Trottier, et al. [1995] Gene 158:263-268) and by an in situ transient transfection assay in rat liver (Park, Y., et al. [1996]. J. Biol. Chem. 271:23725-23728). Deletion mutations of this fragment indicated that the 88-bp stretch from -2258 to -2170 was the minimal sequence that could mediate phenobarbital induction in the in situ system if single copies of the deleted fragments fused to the CYP2C1 proximal promoter were assayed. If three copies of the fragments were present, 5' and 3' deletions defined a minimal 37-bp core fragment, which, although necessary for phenobarbital responsiveness, was not sufficient unless additional sequence was present at either end, suggesting that redundant elements were present in the two flanking regions. Site-specific mutagenesis of an NF-1 site within the 88-bp fragment and linker scanning mutagenesis across the fragment indicated that the NF-1 site and a region to the 5' side of the site contributed to the magnitude of the response, but neither the NF-1 mutations nor any of the linker scanning mutations eliminated the response to phenobarbital. Mutation in a region 3' of the NF-1 site resulted in elevated basal expression without substantial effects on phenobarbital-induced expression. Binding of NF-1 to the 37-bp core fragment was established by gel-shift competition studies and by supershifts of the protein-DNA complexes by antisera to NF-1. Additional protein-DNA complexes were detected in the regions flanking the NF-1 site. These studies indicate that the CYP2B2 phenobarbital-responsive enhancer contains multiple constitutive and phenobarbital-responsive elements. Binding of nuclear proteins from control or phenobarbital-treated animals in vitro to this region was very similar. The only difference detected was a complex that was substantially reduced by phenobarbital treatment and mapped to the 3' side of the NF-1 site.

Epitope mapping of T4 endonuclease VII with monoclonal antibodies reveals importance of both ends of the protein for target binding

Endonuclease VII (endo VII) of bacteriophage T4 is a Holliday-structure resolving enzyme that can also recognize many other defects in DNA via an altered secondary structure. The protein has a molecular mass of 18 kDa and exists as a dimer in solution. Here we report the production and characterization of monoclonal antibodies (mAbs) directed against the highly purified enzyme. From one fusion 15 hybrid cell lines producing mAbs with high affinity for endo VII could be established. The mAbs were used for epitope mapping of the protein by using N-terminal, C-terminal and internal peptides of endo VII as antigens in enzyme-linked immunoabsorbant assays. Three classes of mAbs were distinguished as follows: (1) the predominant class with 13 mAbs recognized a C-terminal epitope located between amino acid residues 115 and 145; (2) a second class, represented by one mAb, recognized an epitope located at the N terminus between amino acid residues 16 and 65; (3) a third class, represented by one mAb, recognized an epitope built from nearly the entire native protein including amino acid residues from the C and N terminus of endo VII. The latter finding suggests close proximity of the two ends, which are provided apparently by the same monomer, since the mAb from class III does also react with a mutant protein deficient in dimerization. Internal sequences of endo VII between amino acid residues 78 and 145 did not react with any of the mAbs.

A conserved proline-rich sequence between the N-terminal signal-anchor and catalytic domains is required for assembly of functional cytochrome P450 2C2

In cytochrome P450 2C2, the region which links the N-terminal signal anchor with the catalytic domain contains a highly conserved proline-rich region with the sequence, 30-PPGPTPFP-37. Mutation of proline-30 or proline-33 diminished activities of the mutants expressed in COS-1 cells (Chen, C., and Kemper, B. (1996) J. Biol. Chem. 271, 28697-28611). Substitution of alanine, proline, or arginine for glycine-32 abolished laurate hydroxylase activity of the proteins expressed in COS-1 cells, which suggests that this residue is also functionally important. To determine the basis for the decreased activity in COS-1 cells, the activities and spectral properties of mutant proteins expressed in insect cells and bacteria were determined. Substitution of alanine for either proline-30 or -33 resulted in reduced expression in insect cells of functional cytochrome P450 hemoprotein and an increase in the expression of inactive cytochrome P420. In contrast, substitution of alanine for proline-31, -35, or -37 resulted in hemoproteins with spectra similar to cytochrome P450 2C2 so that the amount of cytochrome P450 expressed in insect cells correlated with the activities of the mutants in COS-1 cells. The laurate hydroxylase activities per nanomole of cytochrome P450 in insect microsomes were similar for wild type and all mutants, indicating that, once folded, the catalytic activity of membrane-bound cytochrome P450 was not affected by the mutations. Expression in bacteria resulted in diminished expression of cytochrome P450 for all mutants, with the greatest decrease for the proline-30 and -33 mutants, and increased cytochrome P420. In contrast to the insect cell studies, the proline-30 and -33 mutants were inactive, while the other mutants had specific activities 30-70% of cytochrome P450 2C2. These data are consistent with a role for the proline-rich region in efficient assembly of cytochrome P450 2C2 in eukaryotic cells. Mutations of this region also may affect the conformational integrity of the proteins, which was revealed by assays of solubilized bacterially expressed proteins.

Enzymatic mutation detection. Procedure for screening and mapping of mutations by immobilised endonuclease VII

Endonuclease VII (endo VII) binds to non-pairing nucleotides in DNA. This served as the basis for the development of a mutation detection assay involving immobilised endo VII and heteroduplex DNAs made by hybridisation of mutant and wild type DNA. The use of microtiter plates allows screening of large numbers of samples. Localisation of mutations in positive samples can be done in the same assay in a second optional step.

Repeated sleep deprivation once versus twice a week in combination with amitriptyline

OBJECTIVE

Although a combination of antidepressive pharmacotherapy with repeated sleep deprivation therapy has proved to be an effective and easily applied treatment strategy, no systematic study investigating the most favourable interval between the sleep deprivation trials is available.

METHOD

In a cross-over design, 44 patients with a major depressive episode (ICD-10) were randomly allocated to 4 weeks treatment with amitriptyline (150 mg/d) in combination with either late sleep deprivation (of the second half of the night, LSD) twice weekly during week 1 and 2 followed by LSDs once weekly during week 3 and 4 or vice versa. Two hypotheses were tested: Does LSD twice weekly during week 1 and 2 accelerate the clinical response compared with LSD once weekly? Does LSD twice weekly during week 3 and 4 improve the response rate compared with LSD once weekly?

RESULTS

According to both observer rating (Hamilton Rating for Depression, 21-item version) and self-rating (Visual Analogue Mood Scale), no significant differences could be ascertained between the groups compared at any time of the investigation. With respect to drop-outs and immediate LSD effects there is a trend for patients undergoing twice weekly LSDs followed by once weekly LSD trials to have a more favourable treatment course than the control group.

CONCLUSION

The hypotheses tested were answered in the negative. "High dose" LSD administration does not prove to be clearly superior to "low dose" LSD. This finding is in line with most of the corresponding data on antidepressive pharmacotherapy.

Phenobarbital alters protein binding to the CYP2B1/2 phenobarbital-responsive unit in native chromatin

Phenobarbital is a classical inducer of the drug metabolizing cytochrome P450 genes, but the molecular mechanism of induction has not been elucidated. Functional analyses have identified a phenobarbital-responsive unit in the rat CYP2B1/2 and mouse Cyp2b10 genes about -2.3 kilobase pairs from the transcriptional start site, but little or no changes in protein binding to this region were observed in vitro. To examine the role of chromatin structure, protein binding to the phenobarbital-responsive unit assessed by in vitro DNase I footprinting was compared with that assessed by DNase I in vivo footprints in native chromatin. A region centered on a putative nuclear factor-1 site was the major protected region in in vitro footprints, and there were no detectable differences in binding between extracts from control and phenobarbital-treated animals. In contrast, phenobarbital treatment dramatically altered the protection pattern in native chromatin. In control samples a core region of about 25 base pairs (bp) centered on the nuclear factor-1 site was protected. However, after phenobarbital treatment, the protection of this core region was increased, and more dramatically the region of protection was extended 20 bp to either side so that a total of about 60 bp were protected. These results provide the first evidence that phenobarbital treatment alters the composition or architecture of proteins binding to the phenobarbital-responsive unit region and indicate that chromatin structure is important in this process. Because proteins are bound to the region in the untreated animal, the mechanism of induction involves the activation of proteins bound to the region and possibly recruitment of additional regulatory proteins rather than conversion of a closed chromatin structure to an open one that can bind regulatory factors.

Efficient assembly of functional cytochrome P450 2C2 requires a spacer sequence between the N-terminal signal anchor and catalytic domains

Cytochromes P450 (P450) are anchored to the endoplasmic reticulum membrane by an N-terminal transmembrane sequence with the catalytic domain facing the cytoplasmic side. Within the peptide sequence linking these two domains in P450 2C2 is a glycine-rich region from residues 22 to 28. To examine the role of this region, deletion and substitution mutations were constructed, and the activities and spectral properties were determined for the mutant proteins expressed in COS-1 cells, insect cells, and bacteria. Deletion of residues 22 to 28 or substitution of 7 valines for this region inactivated the proteins in COS-1 cells, and no P450 species was detected for these mutations in bacteria or insect cells. Substitution of the three glycine residues with alanine or proline or the entire sequence from 22 to 28 with 7 alanines did not reduce lauric acid hydroxylase activity of the proteins expressed in COS-1 cells. Reducing the number of alanines substituted to 4, 3, and 2 progressively decreased activity in COS-1 cells to undetectable levels when 2 alanines were substituted. The loss of activity in COS-1 cells correlated with decreased expression of hemoprotein with a reduced difference spectrum of 450 nm (P450 species) and a corresponding increase in the inactive P420 species in insect cells and bacteria. The activities expressed per nanomole of P450 in insect microsomes were similar for P450 2C2 and the alanine substitution mutants, including the mutant with 2 alanines which was inactive in COS-1 cells. The rates of conversion of P450 to P420 resulting from incubation at 48 degrees C in vitro were not changed sufficiently to explain the increase in expressed P420 observed for the mutants with 3 or 7 alanines substituted. These data are consistent with a role for the residue 22-28 region as a linker that facilitates the folding of P450; however, once the protein is properly folded into the functional P450 species, this region has little influence on the stability and activity of the enzyme.

Identification of amino acids of endonuclease VII essential for binding and cleavage of cruciform DNA

Endonuclease VII is a Holliday-structure-resolving enzyme of bacteriophage T4. The active protein is a homodimer with 157 amino acids/monomer. An amber mutation (amE727 in codon 151) inactivates the nuclease completely, indicating the importance of the seven C-terminal amino acids for nucleolytic activity. The influence of these amino acids on cruciform-DNA binding and cleavage was investigated through functional analysis of C-terminal-truncated proteins derived from deletion constructs. It was found that the three C-terminal amino acids are not necessary for binding and cleavage. A transition from active to inactive protein occurs gradually with truncations of the next four amino acids. Reduction of DNA-binding ability, as measured by electrophoretic mobility shift assays, was determined to be the primary defect in the cleavage-deficient proteins. This was further concluded by the finding that EVII-(1-150)-peptide(amber), a protein with fairly low affinity to cruciform DNA, contributes cleavage activity to reactions of wild-type EVII with cruciform DNA. [Asp62]EVII-(1-156)-peptide lacking one C-terminal amino acid, contains a point mutation in codon 62 that eliminates the nucleolytic activity of the protein while retaining its DNA-binding proficiency. By mixing binding-deficient and cleavage-deficient mutants in the same assay, cleavage of cruciform DNA resumed. Evidence is presented that complementation occurs by heterodimer formation. Our results show that the zinc-binding motif of EVII is not sufficient for cruciform-DNA binding.

Inhibition of Holliday structure resolving endonuclease VII of bacteriophage T4 by recombination enzymes UvsX and UvsY

Proteins UvsX, UvsY and Endonuclease VII (Endo VII) of bacteriophage T4 are required for DNA recombination, replication and repair. Endo VII is the product of gene 49 (gp49) and essential for resolution of branches from newly made DNA, prior to packaging into preformed heads. The ability of Endo VII to resolve Holliday structures in vitro suggested an in vivo function for the resolution of recombination intermediates, generated by UvsX and UvsY during the early infection cycle. Here we report results which contrast with this hypothesis. It is shown that the potent endonucleolytic activity of Endo VII with branched DNAs is inhibited in strand transfer reactions by the strand transferase UvsX, and more strongly by the accessory protein UvsY in vitro. The inhibitory effect of UvsX or UvsY is also seen in reactions with Endo VII using two synthetic cruciform DNAs and a C/C-mismatch containing substrate. Low concentrations of UvsY protein (12 ng or 0,76 pmol) were sufficient to reduce the cleavage efficiency of 30 units of Endo VII (about 16 fmol) to 50%. The inhibition is due to a direct protein-protein interaction between Endo VII, UvsX and UvsY as suggested by electrophoretic mobility shift assays (EMSAs). These results were confirmed through affinity chromatography, where UvsX and UvsY bound to Endo VII, immobilized on a NHS-activated Sepharose matrix. This is the first identification of phage-encoded proteins which modulate the potent endonucleolytic activity of gp49 in vitro.