Activity and function of rabbit muscle-specific creatine kinase at low temperature by mutation at gly 268 to asn 268 (original) (raw)

Rabbit Muscle Creatine Kinase: Consequences of the Mutagenesis of Conserved Histidine Residues †

George Kenyon

Biochemistry, 1996

View PDFchevron_right

Conformationally restricted creatine analogs and substrate specificity of rabbit muscle creatine kinase

Thomas Leyh

Biochemistry, 1980

View PDFchevron_right

Creatine kinase. A new crystal form providing evidence of subunit structural homogeneity

John Liddell

Journal of Molecular Biology, 1978

View PDFchevron_right

Purification and crystallization of creatine kinase from rabbit skeletal muscle

Robert Stroud

Journal of Biological Chemistry, 1986

View PDFchevron_right

Affinity labeling of creatine kinase by N-(2,3-epoxypropyl)-N-amidinoglycine

George Kenyon

Journal of Biological Chemistry, 1979

View PDFchevron_right

High salt concentrations induce dissociation of dimeric rabbit muscle creatine kinase

Dimer Couthon

Biochimica Et Biophysica Acta-protein Structure and Molecular Enzymology, 1997

View PDFchevron_right

Mutagenesis of Two Acidic Active Site Residues in Human Muscle Creatine Kinase: Implications for the Catalytic Mechanism

Pan-Fen Wang

Biochemistry, 2001

View PDFchevron_right

Exploring the Role of the Active Site Cysteine in Human Muscle Creatine Kinase

Pan-Fen Wang

Biochemistry, 2006

View PDFchevron_right

Subunit-selective chemical modifications of creatine kinase. Evidence for asymmetrical association of the subunits

Chemda Degani

Biochemistry, 1979

View PDFchevron_right

Generation of an Active Monomer of Rabbit Muscle Creatine Kinase by Site-Directed Mutagenesis: The Effect of Quaternary Structure on Catalysis and Stability †

Paul Edmiston

Biochemistry, 2003

View PDFchevron_right

Structural Changes of Creatine Kinase upon Substrate Binding

Theo Wallimann

Biophysical Journal, 1998

View PDFchevron_right

Crystal structure of rabbit muscle creatine kinase

Mohana Rao

FEBS Letters, 1998

View PDFchevron_right

Folding pathway for partially folded rabbit muscle creatine kinase

Wen-Bin Ou

Biochemistry and Cell Biology, 2001

View PDFchevron_right

Properties of a CH3-blocked creatine kinase with altered catalytic activity. Kinetic consequences of the presence of the blocking group

Edward T Maggio

The Journal of biological chemistry, 1977

View PDFchevron_right

Direct determination of creatine kinase equilibrium constants with creatine or cyclocreatine as substrate

Patrizia LoPresti

Biochimica et Biophysica Acta (BBA) - Protein Structure and Molecular Enzymology, 1989

View PDFchevron_right

Relating Structure to Mechanism in Creatine Kinase

George Kenyon

Critical Reviews in Biochemistry and Molecular Biology, 2005

View PDFchevron_right

The active site histidines of creatine kinase. A critical role of His 61 situated on a flexible loop

Martin Stolz

Protein Science, 2008

View PDFchevron_right

Limited proteolysis of creatine kinase. Implications for three-dimensional structure and for conformational substates

Theo Wallimann

Biochemistry, 1993

View PDFchevron_right

Atypical Serum Creatine Kinase Isoenzyme Pattern Caused by Complexing of Creatine Kinase-BB with Immunoglobulins G and A

Evangelia Vretou

Clinical Chemistry and Laboratory Medicine, 2000

View PDFchevron_right

Creatine Kinase

Mahmoud Aminlari

SpringerReference

View PDFchevron_right

Structural asymmetry and intersubunit communication in muscle creatine kinase

Ronald Viola

Acta Crystallographica Section D-biological Crystallography, 2007

View PDFchevron_right

Conformational changes and inactivation of rabbit muscle creatine kinase in dimethyl sulfoxide solutions

Wen-Bin Ou

Biochemistry and Cell Biology, 2002

View PDFchevron_right

Phosphorylation of chicken brain-type creatine kinase affects a physiologically important kinetic parameter and gives rise to protein microheterogeneity in vivo

Hans Eppenberger, Thierry Soldati

FEBS Letters, 1990

View PDFchevron_right

The primary structure of chicken B-creatine kinase and evidence for heterogeneity of its mRNA

Urs Rosenberg

Nucleic Acids Research, 1986

View PDFchevron_right

Why is creatine kinase a dimer? Evidence for cooperativity between the two subunits

Theo Wallimann

Biochimica et Biophysica Acta (BBA) - Protein Structure and Molecular Enzymology, 2000

View PDFchevron_right

A conserved negatively charged cluster in the active site of creatine kinase is critical for enzymatic activity

Theo Wallimann

Journal of Biological Chemistry, 2000

View PDFchevron_right

Activity of creatine kinase in a contracting mammalian muscle of uniform fiber type

Eric McFarland

Biophysical Journal, 1994

View PDFchevron_right

A comparative study of human muscle and brain creatine kinases expressed in Escherichia coli

Patricia Babbitt

2000

View PDFchevron_right

The nature and reactivity of the ‘essential’ thiol in rabbit muscle creatine kinase III (EC 2.7.3.2)

Aila Keto

Biochemical and Biophysical Research Communications, 1982

View PDFchevron_right

Molecular characterization of the creatine kinases and some historical perspectives

Jaime Boero

Bioenergetics of the Cell: Quantitative Aspects, 1998

View PDFchevron_right

Occurrence of Heterogenous Forms of the Subunits of Creatine Kinase in Various Muscle and Nonmuscle Tissues and Their Behaviour during Myogenesis

Urs Rosenberg

European journal of biochemistry, 1981

View PDFchevron_right

Muscle Creatine Kinase-deficient Mice

philippe mateo

Journal of Biological Chemistry, 1995

View PDFchevron_right