The Creatine Phosphoryltransfer Reaction in Iodoacetate-Poisoned Muscle

The iodoacetate-nitrogen-poisoned muscle offers the possibility of studying the stoichiometry of the single muscle twitch since metabolic resynthesis by glycolysis and oxidative phosphorylation are blocked, and there remains as an energy source only the creatine phosphoryltransfer system, creatine phosphate reacting with adenosinediphosphate to give the triphosphate and creatine. It is shown, preparatory to a determination of the amount of phosphocreatine split in a single twitch, that iodoacetate does not inhibit creatine phosphoryltransferase at concentrations which block glycolysis. An analysis is developed which assumes that the transferase maintains the creatine phosphoryl transfer reaction in equilibrium following contraction, and further that the creatine phosporyltransfer reaction and the myokinase reaction are isolated in muscle. On the basis of this analysis and the data obtained, an estimate of the equilibrium constant of the creatine phosphoryl reaction in muscle is obtained which agrees with values determined in vitro. Using the estimated equilibrium constant, and the concentrations of creatine, creatine phosphate, and adenosinetriphosphate found, a value for the concentration of free adenosinediphosphate is obtained which is considerably less than that found by direct chemical analysis.     

Localization of melanin synthesis within the pigment cell: Determination by a combination of electron microscopic autoradiography and topographic planimetry

Summary Localization of melanin synthesis within the pigment cells of the Cloudman S-91 mouse melanoma was determined by means of a combination of high resolution autoradiography and topographic planimetry. Initial melanin biosynthesis occurred predominantly in the endoplasmic reticulum and associated ribonucleoprotein particles of the melanocytes. By measuring a number of cell organelles and employing the index of relative specific localization it could be shown that the nucleus and mitochondria are of little or no importance in the process of melanogenesis.This investigation has been supported by the following research grants: CA 06548 CB, NIH, PHS and an Institutional Grant from the American Cancer Society (to H. M. H.); CA-05887, NIH, PHS (to A. S. Z.); M-00388 and NB-00782, NIH, PHS (to J. F. H.). One of us (H. M. H.) holds a Research Cancer Development Award (5-K 3-GM-2634) of the National Institute of General Medical Sciences, Public Health Service.We are grateful to Mr. Ronald Abler for his help with the topographic measurements; to Dr. Erhard Haus for help and advice; to Mr. J. Thornby and Mr. A. P. Basu for assistance with the statistical aspects of this study; and to Mrs. Lenore Mottaz, Miss Bernice Uittenbogaard, and Mrs. Judith Strong for careful technical assistance.     

Eosinophil degranulation. An immunologic determinant in the pathogenesis of the Mazzotti reaction in human onchocerciasis

Onchocerciasis patients treated with diethylcarbamazine often undergo a severe inflammatory response, the Mazzotti reaction. To assess the eosinophil's role in the pathogenesis of the Mazzotti reaction, we obtained serial blood, plasma, and skin biopsy specimens from 21 heavily infected patients and 3 endemic controls, both before and during therapy with diethylcarbamazine. Samples were analyzed for blood eosinophils, plasma levels of eosinophil granule major basic protein (MBP) and eosinophil-derived neurotoxin, eosinophil infiltration and eosinophil and mast cell degranulation in the skin. After the first dose of diethylcarbamazine, blood eosinophils fell from a pre-treatment level of 888 +/- 111 to 203 +/- 42 cells/mm3 at 8 h. This decrease was followed by a marked eosinophilia developing over the remaining 7 days of treatment and 14 days of follow-up. Plasma eosinophil-derived neurotoxin levels increased from 56 +/- 4 ng/ml pretreatment to a peak of 82 +/- 9 ng/ml at 8 h and returned to pretreatment levels by 48 h. Beginning at 12 h, plasma MBP levels increased from 730 +/- 74 ng/ml pretreatment to a peak of 1140 +/- 74 ng/ml after 5 days. Pretreatment skin biopsies stained for MBP by immunofluorescence showed a bright fibrillar pattern in the dermis consistent with chronic eosinophil degranulation; the MBP was localized on elastic tissue fibers. After treatment, skin biopsy specimens showed both the pretreatment fibrillar MBP staining pattern as well as focal eosinophil degranulation. Deposition of MBP around microfilariae in the papillary dermis was visible as early as 1.5 h. The lowest blood eosinophil levels and peak plasma eosinophil-derived neurotoxin levels coincided with the infiltration and degranulation of eosinophils in the skin. Mast cell degranulation in the skin was maximal by the first posttreatment biopsy (1.5 h) coincident with the beginning of eosinophil degranulation. Although the pathogenesis of the Mazzotti reaction is clearly complex, our results indicate that eosinophil degranulation is characteristic of the response and that it occurs with a time course suggestive of a role for the eosinophil in determining the clinical and pathologic manifestations of the reaction.     

Physical mapping of the von Recklinghausen neurofibromatosis region on chromosome 17

The von Recklinghausen neurofibromatosis (NF1) locus has been linked to chromosome 17, and recent linkage analyses place the gene on the proximal long arm. NF1 probably resides in 17q11.2, since two unrelated NF1 patients have been identified who possess constitutional reciprocal translocations involving 17q11.2 with chromosomes 1 and 22. We have used a somatic-cell hybrid from the t(17;22) individual, along with other hybrid cell lines, to order probes around the NF1 locus. An additional probe, 17L1, has been isolated from a NotI linking library made from flow-sorted chromosome 17 material and has been mapped to a region immediately proximal to the translocation breakpoint. While neither NF1 translocation breakpoint has yet been identified by pulse-field gel analysis, an overlap between two probes, EW206 and EW207, has been detected. Furthermore, we have identified the breakpoint in a non-NF1 translocation, SP-3, on the proximal side of the NF1 locus. This breakpoint has been helpful in creating a 1,000-kb pulsed-field map, which includes the closely linked NF1 probes HHH202 and TH17.19. The combined somatic-cell hybrid and pulsed-field gel analysis we report here favors the probe order D17Z1-HHH202-TH17.19-CRYB1-17L1-NF1- (EW206, EW207, EW203, L581, L946)-(ERBB2, ERBA1). The agreement in probe ordering between linkage analysis and physical mapping is excellent, and the availability of translocation breakpoints in NF1 should now greatly assist the cloning of this locus.     

Molecular cloning of a gene encoding a Chlamydia psittaci 57-kDa protein that shares antigenic determinants with ca. 60-kDa proteins present in many Gram-negative bacteria

In order to develop reagents to study the immune response of guinea pigs to infection by Chlamydia psittaci guinea pig inclusion conjunctivitis strain (GPIC), we constructed a plasmid clone bank with C. psittaci DNA. One of the recombinant clones isolated produced large amounts of a 57-kilodalton (kDa) protein that was immunoreactive with sera from GPIC infected guinea pigs. While investigating this recombinant protein, we discovered that all the Gram-negative bacteria analyzed so far have immunoreactive proteins of similar size. This protein seems to be a 'common antigen' already described in various Gram-negative bacteria.     

Redox intermediates of Desulfovibrio gigas [NiFe] hydrogenase generated under hydrogen. M?ssbauer and EPR characterization of the metal centers

The hydrogenase (EC 1.2.2.1) of Desulfovibrio gigas is a complex enzyme containing one nickel center, one [3Fe-4S] and two [4Fe-4S] clusters. Redox intermediates of this enzyme were generated under hydrogen (the natural substrate) using a redox-titration technique and were studied by EPR and M?ssbauer spectroscopy. In the oxidized states, the two [4Fe-4S]2+ clusters exhibit a broad quadrupole doublet with parameters (apparent delta EQ = 1.10 mm/s and delta = 0.35 mm/s) typical for this type of cluster. Upon reduction, the two [4Fe-4S]1+ clusters are spectroscopically distinguishable, allowing the determination of their midpoint redox potentials. The cluster with higher midpoint potential (-290 +/- 20 mV) was labeled Fe-S center I and the other with lower potential (-340 +/- 20 mV), Fe-S center II. Both reduced clusters show atypical magnetic hyperfine coupling constants, suggesting structural differences from the clusters of bacterial ferredoxins. Also, an unusually broad EPR signal, labeled Fe-S signal B', extending from approximately 150 to approximately 450 mT was observed concomitantly with the reduction of the [4Fe-4S] clusters. The following two EPR signals observed at the weak-field region were tentatively attributed to the reduced [3Fe-4S] cluster: (i) a signal with crossover point at g approximately 12, labeled the g = 12 signal, and (ii) a broad signal at the very weak-field region (approximately 3 mT), labeled the Fe-S signal B. The midpoint redox potential associated with the appearance of the g = 12 signal was determined to be -70 +/- 10 mV. At potentials below -250 mV, the g = 12 signal began to decrease in intensity, and simultaneously, the Fe-S signal B appeared. The transformation of the g = 12 signal into the Fe-S signal B was found to parallel the reduction of the two [4Fe-4S] clusters indicating that the [3Fe-4S]o cluster is sensitive to the redox state of the [4Fe-4S] clusters. Detailed redox profiles for the previously reported Ni-signal C and the g = 2.21 signal were obtained in this study, and evidence was found to indicate that these two signals represent two different oxidation states of the enzyme. Finally, the mechanistic implications of our results are discussed.