Elizabeth M. Furter‐Graves scite author profile

Chemical modification of rabbit muscle creatine kinase (CK) with thiol-specific reagents led to partial or complete inactivation of the enzyme. Using site-directed mutagenesis, we have substituted the corresponding reactive Cys278 in the chicken cardiac mitochondrial creatine kinase (Mib-CK) with either glycine, serine, alanine, asparagine, or aspartate. The resulting mutant Mib-CK enzymes showed qualitatively similar changes in their enzymatic properties. In both directions of the CK reaction, a shift of the pH optimum to lower values was observed. Mutant Mib-CKs were severalfold more sensitive to inhibition by free ADP in the reverse reaction (ATP synthesis) and to free ATP in the forward reaction (phosphocreatine synthesis). With the exception of C278D, all mutant enzymes were specifically activated by chloride and bromide anions. C278D and wild-type Mib-CK were significantly inhibited under the same conditions. At low chloride concentrations, the Vmax of C278D was about 12-fold higher than that of C278N. Thus, Cys278 probably provides a negative charge which is directly or indirectly involved in maximizing CK activity. Under near-optimal conditions in the reverse reaction, mutants C278G and C278S showed about an 11-fold increase in Km(PCr), but only 1.7- and 2.8-fold reductions in Vmax, respectively, compared to wild-type Mib-CK. Thus, the reactive cysteine clearly is not essential for catalysis. For rabbit muscle CK, substrate binding had been shown to be synergistic (i.e., Kd > Km). We confirmed this finding for wild-type Mib-CK by determining the Kd and Km values for both substrates in the forward reaction.(ABSTRACT TRUNCATED AT 250 WORDS)

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The tryptophan residues of mitochondrial creatine kinase: Roles of Trp‐223, Trp‐206, and Trp‐264 in active‐site and quaternary structure formation

Groß

Furter‐Graves

Wallimann

et al. 1994

Protein Science

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The 5 tryptophan residues of chicken sarcomeric mitochondrial creatine kinase (Mi,-CK) were individually replaced by phenylalanine or cysteine using site-directed mutagenesis. The mutant proteins were analyzed by enzyme kinetics, fluorescence spectroscopy, circular dichroism, and conformational stability studies. In the present work, Trp-223 is identified as an active-site residue whose replacement even by phenylalanine resulted in 296% inactivation of the enzyme. Trp-223 is responsible for a strong (18-21%) fluorescence quenching effect occurring upon formation of a transition state-analogue complex (TSAC; Mib-CK .creatine.MgADP .NO,-), and Trp-223 is probably required for the conformational change leading to the TSAC-induced octamer dissociation of Mib-CK.Replacement of Trp-206 by cysteine led to a destabilization of the active-site structure, solvent exposure of Trp-223, and to the dissociation of the Mib-CK dimers into monomers. However, this dimer dissociation was counteracted by TSAC formation or the presence of ADP alone. Trp-264 is shown to be located at the dimerdimer interfaces within the Mib-CK octamer, being the origin of another strong (25%) fluorescence quenching effect, which was observed upon the TSAC-induced octamer dissociation. Substitution of Trp-264 by cysteine drastically accelerated the TSAC-induced dissociation and destabilized the octameric structure by one-fourth of the total free interaction energy, probably by weakening hydrophobic contacts. The roles of the other 2 tryptophan residues, Trp-213 and Trp-268, could be less well assigned.

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Creatine Kinase Isoenzymes in Chicken Cerebellum: Specific Localization of Brain‐type Creatine Kinase in Bergmann Glial Cells and Muscle‐type Creatine Kinase in Purkinje Neurons

Hemmer

Zanolla

Furter‐Graves

et al. 1994

Eur J of Neuroscience

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Creatine kinase isoenzymes were localized in the chicken cerebellum by the use of isoenzyme-specific anti-chicken creatine kinase antibodies. Brain-type creatine kinase was found in high amounts in the molecular layer, particularly in Bergmann glial cells but also in other cells of the cerebellar cortex, e.g. in astrocytes and in the glomerular structures, as well as in cells of the deeper nuclei. A mitochondrial creatine kinase isoform was primarily localized to the glomerular structures in the granule cell layer and was also identified in Purkinje neurons. Surprisingly, a small amount of the muscle-type creatine kinase isoform was identified in cerebellar extracts by immunoprecipitation, immunoblotting and native enzyme electrophoresis, and was shown to be localized exclusively in Purkinje neurons. Cell type-specific expression of brain- and muscle-type creatine kinase in Bergmann glial cells and Purkinje neurons, respectively, may serve to adapt cellular ATP regeneration to the different energy requirements in these specialized cell types. The presence of brain-type creatine kinase in Bergmann glial cells and astrocytes is discussed within the context of the energy requirements for ion homeostasis (K+ resorption), as well as for metabolite and neurotransmitter trafficking. In addition, the presence of muscle-type creatine kinase in Purkinje neurons, which also express other muscle-specific proteins, is discussed with respect to the unique calcium metabolism of these neurons and their role in cerebellar motor learning.

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DNA sequence elements required for transcription initiation of the Schizosaccharomyces pombe ADH gene in Saccharomyces cerevisiae

Furter‐Graves¹,

Hall²

1990

Molec. Gen. Genet.

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The roles of the TATA element and sequences near the mRNA initiation site in specifying the location of initiation sites in Saccharomyces cerevisiae were examined, using the Schizosaccharomyces pombe ADH gene. The importance of spacing was demonstrated by analysis of a series of deletions that removed from 8-50 bp between the TATA element and ATG translation initiation site of this gene. Primer extension mapping showed that increasing deletion length is associated with a progressive shift downstream in the location of the initiation sites. The distance of a given site from the promoter affected the relative ability of the site to be utilized for initiation. For this gene, a permissive region for transcription initiation exists between 55 and 125 bases downstream of the TATA element, and a zone of 75-115 bases allows maximal usage of an initiation site. The presence of a TATA sequence was shown to be necessary in S. cerevisiae for maintaining the location of this "window" of initiation. The TATA sequence is essential for function of the gene in S. pombe. This gene, as well as the majority of the 63 S. cerevisiae genes surveyed, uses initiation sites which fit a PyAA/T(Pu) consensus. Cis-acting mutations were recovered which restored ADH activity to a deletion allele that initiates its mRNAs downstream of the ATG. DNA sequence and transcript analysis with these mutants confirmed the requirement of proper spacing and conformity of initiation sites to the PyAA/T(Pu) consensus for efficient transcript initiation.

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Role of a small RNA pol II subunit in TATA to transcription start site spacing

Furter‐Graves¹,

Hall

Furter³

1994

Nucl Acids Res

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The yeast shi mutation affects the spacing between the TATA promoter element and transcription initiation sites; for the H2B and ADH1 genes, a series of start sites located approximately 50-80 bp downstream of TATA is used in addition to the wild-type initiation sites located at around 100 bp from TATA (1). Here, the yeast SHI wild-type gene has been isolated by complementation and shown to be identical to RPB9, the gene encoding a small subunit of RNA polymerase II. A point mutation in the shi gene, changing a cysteine residue in a putative zinc ribbon motif into a phenylalanine residue, was demonstrated to permit the observed usage of upstream initiation sites. Deletion of the non-essential SHI gene also results in usage of upstream initiation sites and causes conditional growth defects.

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