A Geospatial Analysis of Severe Firearm Injuries Compared to Other Injury Mechanisms: Event Characteristics, Location, Timing, and Outcomes

OBJECTIVES

Relatively little is known about the context and location of firearm injury events. Using a prospective cohort of trauma patients, we describe and compare severe firearm injury events to other violent and nonviolent injury mechanisms regarding incident location, proximity to home, time of day, spatial clustering, and outcomes.

METHODS

This was a secondary analysis of a prospective cohort of injured children and adults with hypotension or Glasgow Coma Scale score ≤ 8, injured by one of four primary injury mechanisms (firearm, stabbing, assault, and motor vehicle collision [MVC]) who were transported by emergency medical services to a Level I or II trauma center in 10 regions of the United States and Canada from January 1, 2010, through June 30, 2011. We used descriptive statistics and geospatial analyses to compare the injury groups, distance from home, outcomes, and spatial clustering.

RESULTS

There were 2,079 persons available for analysis, including 506 (24.3%) firearm injuries, 297 (14.3%) stabbings, 339 (16.3%) assaults, and 950 (45.7%) MVCs. Firearm injuries resulted in the highest proportion of serious injuries (66.3%), early critical resources (75.3%), and in-hospital mortality (53.5%). Injury events occurring within 1 mile of a patient's home included 53.9% of stabbings, 49.2% of firearm events, 41.3% of assaults, and 20.0% of MVCs; the non-MVC events frequently occurred at home. While there was geospatial clustering, 94.4% of firearm events occurred outside of geographic clusters.

CONCLUSIONS

Severe firearm events tend to occur within a patient's own neighborhood, often at home, and generally outside of geospatial clusters. Public health efforts should focus on the home in all types of neighborhoods to reduce firearm violence.

The Saccharomyces cerevisiae TSC10/YBR265w gene encoding 3-ketosphinganine reductase is identified in a screen for temperature-sensitive suppressors of the Ca2+-sensitive csg2Delta mutant

Saccharomyces cerevisiae csg2Delta mutants accumulate the sphingolipid inositolphosphorylceramide, which renders the cells Ca2+-sensitive. Temperature-sensitive mutations that suppress the Ca2+ sensitivity of csg2Delta mutants were isolated and characterized to identify genes that encode sphingolipid synthesis enzymes. These temperature-sensitive csg2Delta suppressors (tsc) fall into 15 complementation groups. The TSC10/YBR265w gene was found to encode 3-ketosphinganine reductase, the enzyme that catalyzes the second step in the synthesis of phytosphingosine, the long chain base found in yeast sphingolipids. 3-Ketosphinganine reductase (Tsc10p) is essential for growth in the absence of exogenous dihydrosphingosine or phytosphingosine. Tsc10p is a member of the short chain dehydrogenase/reductase protein family. The tsc10 mutants accumulate 3-ketosphinganine and microsomal membranes isolated from tsc10 mutants have low 3-ketosphinganine reductase activity. His6-tagged Tsc10p was expressed in Escherichia coli and isolated by nickel-nitrilotriacetic acid column chromatography. The recombinant protein catalyzes the NADPH-dependent reduction of 3-ketosphinganine. These data indicate that Tsc10p is necessary and sufficient for catalyzing the NADPH-dependent reduction of 3-ketosphinganine to dihydrosphingosine.

Hydroxylation of Saccharomyces cerevisiae ceramides requires Sur2p and Scs7p

The Saccharomyces cerevisiae SCS7 and SUR2 genes are members of a gene family that encodes enzymes that desaturate or hydroxylate lipids. Sur2p is required for the hydroxylation of C-4 of the sphingoid moiety of ceramide, and Scs7p is required for the hydroxylation of the very long chain fatty acid. Neither SCS7 nor SUR2 are essential for growth, and lack of the Scs7p- or Sur2p-dependent hydroxylation does not prevent the synthesis of mannosyldiinositolphosphorylceramide, the mature sphingolipid found in yeast. Deletion of either gene suppresses the Ca2+-sensitive phenotype of csg2Delta mutants, which arises from overaccumulation of inositolphosphorylceramide due to a defect in sphingolipid mannosylation. Characterization of scs7 and sur2 mutants is expected to provide insight into the function of ceramide hydroxylation.

Activation of divalent cation influx into S. cerevisiae cells by hypotonic downshift

Subjecting Saccharomyces cerevisiae cells to a hypotonic downshift by transferring cells form YPD medium containing 0.8 M sorbitol to YPD medium without sorbitol induces a transient rapid influx of Ca2+ and other divalent cations into the cell. For cells grown in YPD at 37 degrees C, this hypotonic downshift increases Ca2+ accumulation 6.7-fold. Hypotonic downshift-induced Ca2+ accumulation and steady-state Ca2+ accumulation in isotonic YPD medium are differentially affected by dodecylamine and Mg2+. The Ca(2+)-influx pathway responsible for hypotonic-induced Ca2+ influx may account for about 10-35% of Ca2+ accumulation by cells growing in YPD. Ca2+ influx is not required for cells to survive a hypotonic downshift. Hypotonic downshift greatly reduces the ability of S. cerevisiae cells to survive a 5-min exposure to 10 mM Cd2+ suggesting that mutants resistant to acute Cd2+ exposure may help identify genes required for hypotonic downshift-induced divalent cation influx.

Serine palmitoyltransferase (scs1/lcb2) mutants have elevated copy number of the L-A dsRNA virus

The microsomal fraction isolated form serine palmitoyltransferase (lcb2/scs1) mutants is enriched in a 90 kDa protein. The protein was identified as the major coat (Gag) protein of the L-A dsRNA virus particles by partial sequencing and by its interaction with anti-Gag antibodies. The total amount of Gag in whole-cell lysates of scs1/lcb2 mutant cells is greater than in wild-type lysates indicating that the enrichment of the protein in the microsomal fraction of scs1/lcb2 mutant cells may result from increased copy number of the L-A dsRNA virus. This is supported by the findings that the mutants also have increased levels of L-A dsRNA. Altered sphingolipid synthesis in the scs1 mutant cells appears to increase the copy number of the L-A viral particles.

Regulation of cellular Mg2+ by Saccharomyces cerevisiae

Regulation of cellular Mg2+ by S. cerevisiae was investigated. The minimal concentration of Mg2+ that results in optimal growth of S. cerevisiae is about 30 microM and a half-maximum growth rate is attained at about 5 microM Mg2+. Since the plasma membrane has an electrical potential greater than 100 mV, passive equilibration of Mg2+ across the plasma membrane would provide sufficient cytosolic Mg2+ (0.1-1 mM). The total cellular Mg2+ of cells grown in synthetic medium containing 1 mM Mg2+ is about 400 nmol/mg protein, most of which is bound to polyphosphate, nucleic acids, and ATP. Total cellular Mg2+ decreases to about 80 nmol/mg protein as the Mg2+ in synthetic growth medium is reduced to 0.02 mM, but remains relatively constant in growth medium containing 1 to 100 mM Mg2+. Cells shifted into Mg(2+)-free medium continue to grow by utilizing the vacuolar Mg2+ stores. Mg(2+)-starved cells replenish vacuolar Mg2+ stores with a halftime of 30 min. following the addition of 1 mM Mg2+ to the growth medium. The data indicate that cytosolic Mg2+ is maintained by the regulation of Mg2+ fluxes across both the vacuolar and plasma membranes.

The Menkes/Wilson disease gene homologue in yeast provides copper to a ceruloplasmin-like oxidase required for iron uptake

The CCC2 gene of the yeast Saccharomyces cerevisiae is homologous to the human genes defective in Wilson disease and Menkes disease. A biochemical hallmark of these diseases is a deficiency of copper in ceruloplasmin and other copper proteins found in extracytosolic compartments. Here we demonstrate that disruption of the yeast CCC2 gene results in defects in respiration and iron uptake. These defects could be reversed by supplementing cells with copper, suggesting that CCC2 mutant cells were copper deficient. However, cytosolic copper levels and copper uptake were normal. Instead, CCC2 mutant cells lacked a copper-dependent oxidase activity associated with the extracytosolic domain of the FET3-encoded protein, a ceruloplasmin homologue previously shown to be necessary for high-affinity iron uptake in yeast. Copper restored oxidase activity both in vitro and in vivo, paralleling the ability of copper to restore respiration and iron uptake. These results suggest that the CCC2-encoded protein is required for the export of copper from the cytosol into an extracytosolic compartment, supporting the proposal that intracellular copper transport is impaired in Wilson disease and Menkes disease.

Suppressors of the Ca(2+)-sensitive yeast mutant (csg2) identify genes involved in sphingolipid biosynthesis. Cloning and characterization of SCS1, a gene required for serine palmitoyltransferase activity

Suppressor mutations in Saccharomyces cerevisiae that block Ca(2+)-induced death of csg2 mutant cells were investigated. These mutants, called scs mutants (suppressor of Ca2+ sensitivity), fall into seven complementation groups (scs1-scs7). All mutant strains in two of the complementation groups (scs1 and scs2) simultaneously acquire a requirement for 10 mM Ca2+, whereas wild type grow with only trace amounts of Ca2+. SCS1 was cloned by complementation of its Ca(2+)-requiring phenotype and found to be homologous to a family of pyridoxal phosphate enzymes that catalyze acyltransfer reactions. Secondary phenotypes of the scs1 mutants indicate that SCS1 is required for serine palmitoyltransferase activity which catalyzes the first committed step in sphingolipid biosynthesis (palmitoyl-CoA + serine-->3-ketosphinganine+CoASH+CO2). Other scs mutants as well as the csg2 null mutant have altered sphingolipid metabolism. The data suggest that sphingolipid metabolism in yeast is either regulated by Ca2+ and/or is required for Ca2+ homeostasis.

Sequence, mapping and disruption of CCC1, a gene that cross-complements the Ca(2+)-sensitive phenotype of csg1 mutants

We have isolated, sequenced, mapped and disrupted a novel gene, CCC1, from Saccharomyces cerevisiae. This gene displays non-allelic complementation of the Ca(2+)-sensitive phenotype conferred by the csg1 mutation. The ability of this gene, in two copies per cell, to reverse the csg1 defect suggests it may have a role in regulating Ca2+ homeostasis. The sequence of CCC1 indicates that it encodes a 322 amino acid, membrane-associated protein. The CCC1 gene is located on the right arm of chromosome XII.

Regulation of cellular Ca2+ by yeast vacuoles

The role of vacuolar Ca2+ transport systems in regulating cellular Ca2+ was investigated by measuring the vacuolar Ca2+ transport rate, the free energy available to drive vacuolar Ca2+ transport, the ability of the vacuole to buffer lumenal Ca2+, and the vacuolar Ca2+ efflux rate. The magnitude of the Ca2+ gradient generated by the vacuolar H+ gradient best supports a 1 Ca2+:2 H+ coupling ratio for the vacuolar Ca2+/H+ exchanger. This coupling ratio along with a cytosolic Ca2+ concentration of 125 nM would give a vacuolar free Ca2+ concentration of approximately 30 microM. The total vacuolar Ca2+ concentration is approximately 2 mM due to Ca2+ binding to vacuolar polyphosphate. The Ca2+ efflux rate from the vacuole is less than the growth rate indicating that the steady-state Ca2+ loading level of the vacuole is dependent mainly on the Ca2+ transport rate and the rate that vacuolar Ca2+ is diluted by growth. Based on the kinetic parameters of vacuolar Ca2+ accumulation in vitro, the maximum rate of Ca2+ accumulation in vivo is expected to be approximately 0.2 nmol of Ca2+ min-1 mg protein-1, a rate that is similar to the cellular Ca2+ accumulation rate. The cytosolic Ca2+ concentration increases from 0.1 microM to 1-2 microM as the extracellular Ca2+ concentration is raised from 0.3 mM to 50 mM. The rise in cytosolic Ca2+ concentration increases cellular Ca2+ from 10 to 300 nmol Ca2+/mg by increasing the rate of vacuolar Ca2+ accumulation but does not significantly alter the cellular growth rate.

A novel protein, CSG2p, is required for Ca2+ regulation in Saccharomyces cerevisiae

Nineteen mutants that lost the ability to grow in 100 mM Ca2+ (but remained insensitive to 50 mM Sr2+) were identified in a screen of approximately 60,000 mutagenized yeast colonies. Cells carrying mutations in the CSG2 gene grow normally in low Ca2+ medium but have decreased growth rates when the Ca2+ concentration is above 10 mM. The csg2 mutant cells accumulate much higher levels of Ca2+ in a compartment that is exchangeable with extracellular Ca2+ but the nonexchangeable Ca2+ pool which predominates in wild-type cells is not influenced. Sr2+ influx is not increased in the csg2 mutant cells. Mg2+ decreases the amount of Ca2+ in the non-exchangeable pool without influencing the csg2-induced exchangeable Ca2+ pool. The data indicate that the csg2 mutation causes a selective increase in Ca2+ accumulation into a pool which is distinct from the vacuolar pool. The CSG2 protein consists of 410 amino acids, contains nine putative transmembrane segments, four potential sites for N-linked glycosylation, and a sequence with homology to the EF-hand Ca(2+)-binding site.

Effect of the general anesthetic halothane on the activity of the transverse tubule Ca(2+)-activated K+ channel

The effect of the general anesthetic halothane on the activity of the rat skeletal muscle Ca(2+)-activated K+ channel in planar lipid bilayers was investigated. Halothane concentrations in the clinical range (1.0-0.2 mM) alter the regulation of the channel by both Ca2+ and membrane potential. At Ca2+ concentrations between 10 and 250 microM and membrane potentials between 0 and -30 mV, halothane significantly decreases the open state probability without changing the channel conductance. The results demonstrate that halothane can act directly on the Ca(2+)-activated K+ channel or its lipid environment to alter the channel gating kinetics.

Oxidation of sulfhydryl groups and inhibition of the (Ca2+ + Mg2+)-ATPase by arsenazo III

In the presence of divalent cations, the metallochromic Ca2+ indicator arsenazo III is reduced by sulfhydryl groups to form an azo anion radical. Reduced arsenazo III is reoxidized back to its original state by oxygen. The formation of the arsenazo III azo anion radical in the presence of sarcoplasmic reticulum vesicles leads to the rapid inhibition of the (Ca2+ + Mg2+)-ATPase. These data indicate that several factors should be considered when arsenazo III is used as a Ca2+ indicator; (1) Functionally important sulfhydryl groups may be oxidized by arsenazo III; (2) the generation of free radicals by arsenazo III reduction may be toxic to the system being studied; (3) the absorbance spectrum of arsenazo III is altered when reduced by sulfhydryl groups.

Optical response of the indicator chlortetracycline to membrane potential

Chlortetracycline is a fluorescent, Ca2+ indicator commonly used to monitor the internal Ca2+ concentration of membrane vesicles and organelles. We have found that the intensity of chlortetracycline fluorescence in the presence of Ca2(+)-loaded liposomes is dependent on the membrane potential of the vesicles as well as the intravesicular Ca2+ concentration. The fluorescence of chlortetracycline was lower when an inside-negative membrane potential was placed across the liposome membrane. Since chlortetracycline diffuses across the membrane in the zwitterionic form, the distribution of chlortetracycline across the membrane should not be strongly dependent on the membrane potential. However, because the proton permeability of phospholipid vesicles is relatively high, the intravesicular proton concentration is dependent on the membrane potential. The binding of Ca2+ to chlortetracycline is dependent on pH in the range of pH 6 to pH 8. Therefore, changes in the intravesicular pH as a result of a change in the membrane potential causes relatively large changes in the chlortetracycline fluorescence signal even when there isn't a change in the Ca2+ concentration.

Raman spectroscopy of synthetic antimicrobial frog peptides magainin 2a and PGLa

Magainin and PGLa are 23- and 21-residue peptides isolated from the skin of the African clawed frog Xenopus laevis. They protect the frog from infection and exhibit a broad-spectrum antimicrobial activity in vitro. The mechanism of this activity involves the interaction of magainin with microbial membranes. We have measured the secondary structure and membrane-perturbing ability of these peptides to obtain information about this mechanism. Our results show that mgn2a forms a helix with an average length of less than 20 A upon binding to liposomes. At high concentrations (50 mg/mL) mgn2a spontaneously solubilizes phosphatidylcholine liposomes at temperatures above the gel-liquid-crystalline phase transition. Mgn2a appears to bind to the surface of liposomes made of negatively charged lipids without spontaneously penetrating the bilayer. Finally, mgn2a and PGLa interact together with liposomes in a synergistic way that enhances the helix content of one or both of the peptides and allows the peptides to more easily penetrate the bilayer. PGLa mixed with a small nonperturbing amount of magainin 2 amide is 25-43 times as potent as PGLa alone at inducing the release of carboxyfluorescein from liposomes. The results suggest that the mechanism of antimicrobial activity does not involve a channel formed by transmembrane helical peptides.

G-protein dependent potentiation of calcium release from sarcoplasmic reticulum of skeletal muscle

Skinned fibre experiments were conducted to determine if guanine nucleotide-binding proteins play a role in excitation-contraction coupling of skeletal muscle. By itself, the GTP-gamma S, a non hydrolysable GTP analogue was unable to induce calcium release from the sarcoplasmic reticulum, even at concentrations as high as 500 microM. However, calcium- or caffeine-induced calcium releases were enhanced by GTP-gamma S in micromolar concentrations. This response was blocked by GDP-beta S or Pertussis toxin. 32P-ADP-ribosylation catalysed by Pertussis toxin, radiolabelled G-protein alpha subunits in the range of 40 kDa on membrane subcellular fractions of rat skeletal muscle. Using Western blot analysis with antibodies raised against the bovine transducin, G-proteins were identified in frog and rat skeletal muscle subcellular fractions. In most of the muscle fractions (plasma membrane, T-tubules, triads, sarcoplasmic reticulum), the anti-beta subunit antibodies recognized a 36 kDa protein which comigrated with transducin beta subunit. It appears therefore that some of the G-proteins identified by ADP-ribosylation or immunostaining in several subcellular fractions from skeletal muscle, are implicated in the modulation of calcium release from sarcoplasmic reticulum. These results suggest that a Pertussis toxin sensitive G-protein is present at the loci of E-C coupling, and that it serves to regulate the calcium release.

Distribution of glucose transporters and insulin receptors in the plasma membrane and transverse tubules of skeletal muscle

The distribution of glucose transporters and of insulin receptors on the surface membranes of skeletal muscle was studied, using isolated plasma membranes and transverse tubule preparations. (i) Plasma membranes from rabbit skeletal muscle were prepared according to Seiler and Fleischer (1982, J. Biol. Chem. 257, 13862-13871), and transverse tubules from rabbit skeletal muscle were prepared according to Rosemblatt et al. (1981, J. Biol. Chem. 256, 8140-8148) as modified by Hidalgo et al. (1983, J. Biol. Chem. 258, 13937-13945). The membranes were identified by the abundance of nitrendipine receptors in the transverse tubules, and their relative absence from the plasma membranes. (ii) Plasma membranes and transverse tubules were also isolated from rat skeletal muscle, according to a novel procedure that isolates both fractions from the same common homogenate. (iii) Glucose transporters were detected by D-glucose protectable binding of the specific inhibitor [3H]cytochalasin B, and insulin receptors were detected by saturable binding of 125I-insulin. The concentration of glucose transporters was about threefold (rabbit) or fivefold (rat) higher in the transverse tubule membrane compared to the plasma membrane, whereas the insulin receptor concentration was about the same in both membranes. These results indicate that the glucose transporters on the surface of the muscle are preferentially segregated to the transverse tubules, and this poses interesting consequences on the functional response of glucose transport to insulin in skeletal muscle.

Effect of halothane on Ca2+-induced Ca2+ release from sarcoplasmic reticulum vesicles isolated from rat skeletal muscle

Halothane induces the release of Ca2+ from a subpopulation of sarcoplasmic reticulum vesicles that are derived from the terminal cisternae of rat skeletal muscle. Halothane-induced Ca2+ release appears to be an enhancement of Ca2+-induced Ca2+ release. The low-density sarcoplasmic reticulum vesicles which are believed to be derived from nonjunctional sarcoplasmic reticulum lack the capability of both Ca2+-induced and halothane-induced Ca2+ release. Ca2+ release from terminal cisternae vesicles induced by halothane is inhibited by Ruthenium red and Mg2+, and require ATP (or an ATP analogue), KCl (or similar salt) and extravesicular Ca2+. Ca2+-induced Ca2+ release has similar characteristics.

The rate of Ca2+ translocation by sarcoplasmic reticulum (Ca2+ + Mg2+)-ATPase measured with intravesicular arsenazo III

Release of Ca2+ from the (Ca2+ + Mg2+)-ATPase into the interior of intact sarcoplasmic reticulum vesicles was measured using arsenazo III, a metallochromic indicator of Ca2+. Arsenazo III was placed inside the sarcoplasmic reticulum vesicles by making the vesicles transiently leaky with an osmotic gradient in the presence of arsenazo III. External arsenazo III was then removed by centrifugation. Addition of ATP to the (Ca2+ + Mg2+)-ATPase in the presence of Ca2+ causes the rapid phosphorylation of the enzyme at which time the bound Ca2+ becomes inaccessible to external EGTA. The release of Ca2+ from the (Ca2+ + Mg2+)-ATPase to the interior of the vesicle measured with intravesicular arsenazo III was much slower indicating that there is an occluded form of the Ca2+-binding site which precedes the release of Ca2+ into the vesicle. The rate of Ca2+ accumulation by sarcoplasmic reticulum vesicles is increased by K+ (5-100 mM) and ATP (50-1000 microM) but the initial rate of Ca2+ translocation measured after the simultaneous addition of ATP and EGTA to vesicles that were preincubated in Ca2+ was not influenced by these concentrations of K+ and ATP.

Osmotic changes of sarcoplasmic reticulum vesicles during Ca2+ uptake

The ATP-dependent accumulation of Ca2+ by sarcoplasmic reticulum vesicles at 37 degrees reaches a peak after approximately 100 sec. The Ca2+-loading level then declines until a steady-state level is reached which is 20% less than the peak value. This spontaneous release of Ca2+ is enhanced by inclusion of maleate in the Ca2+ uptake medium. Increasing the extravesicular osmolarity by the addition of sucrose to the Ca2+ uptake medium prevents spontaneous Ca2+ release and increases the steady-state Ca2+-loading capacity of sarcoplasmic reticulum vesicles. Swelling of sarcoplasmic reticulum vesicles during Ca2+ uptake in medium containing sucrose is indicated by changes in the light-scattering intensity. These experiments indicate that the capacity of sarcoplasmic reticulum vesicles to accumulate Ca2+ is limited by the osmotic gradient generated by the increase in intravesicular Ca2+. Swelling of sarcoplasmic reticulum vesicles during Ca2+ uptake causes spontaneous Ca2+ release.

Optical probe responses on sarcoplasmic reticulum: oxacarbocyanines as probes of membrane potential

The relationship between Ca2+ fluxes and the ion diffusion potential was analyzed on sarcoplasmic reticulum membranes using oxacarbocyanine dyes as optical probes for membrane potential. 3.3'-Diethyloxodicarbocyanine responds to ATP-induced Ca2+ uptake by isolated sarcoplasmic reticulum vesicles with a decrease in absorbance at 600 nm. The optical change is reversed during Ca2+ release from sarcoplasmic reticulum induced by KCl or by ADP and inorganic phosphate. The absorbance changes are largely attributable to the binding of accumulated Ca2+ to the membrane. There is no indication that sustained changes in membrane diffusion potential would accompany pump-mediated Ca2+ fluxes. A large change in the absorbance of 3,3'-diethyloxodicarbocyanine was observed on sarcoplasmic reticulum vesicles under the influence of membrane potential generated by valinomycin in the presence of a K+ gradient or by ionophore A23187 in the presence of a Ca2+ gradient. The maximum of the potential-dependent absorbance change is at 575--580 nm. The potentials generated by valinomycin or ionophore A23187 are short-lived due to the high permeability of sarcoplasmic reticulum membranes for cations and anions. There is no correlation between the direction and magnitude of the artifically imposed membrane potential and the rate of Ca2+ uptake or release by isolated sarcoplasmic reticulum vesicles.

Optical probe responses on sarcoplasmic reticulum. Oxacarbocyanines

Absorbance and fluorescence changes of oxacarbocyanine dyes during ATP-induced Ca2+ transport in rabbit sarcoplasmic reticulum were analyzed. The response of the probes is complex and contains contributions from the binding of Ca2+ and ATP to the membrane. In a medium of 0.12 M KCl and 5 mM MgCl2, the fluorescence of Di-O-C5(3) is decreased by Ca2+ or ATP with apparent dissociation constants of 0.2 and 5 micron, respectively. This suggests that oxacarbocyanines respond to binding of Ca2+ and ATP at the active site of Ca2+ transport ATPase. The effect of ATP is observed in the absence of divalent cations. Further changes in the fluorescence or absorbance of cyanine dyes occur at millimolar concentrations of Ca2+ or during ATP-induced Ca2+ uptake, which can be related to Ca2+ binding to low affinity, relatively nonspecific binding sites on the membrane, that can also bind K+ and Mg2+. The optical changes due to Ca2+ accumulation are most pronounced in media of 0.25 M sucrose and much reduced in 0.12 M KCl and 5 mM MgCl2, in accord with competition by K+ and Mg2+ for the low affinity Ca2+ binding sites. These effects must be taken into account in the evaluation of the magnitude and direction of membrane potential in sarcoplasmic reticulum vesicles during Ca2+ uptake and release.

Optical probe responses on sarcoplasmic reticulum. Merocyanine and oxonol dyes

The fluorescence and absorbance of merocyanine 540 in suspensions of skeletal muscle microsomes is altered by the binding of Ca2+ and other cations to the membrane. The order of effectiveness of various cations in causing this effect is La greater than Ca congruent to Mg greater than K. Competition between Ca2+, Mg2+, and K+ suggests the involvement of low affinity, relatively nonspecific cation binding sites in the process. Changes in the fluorescence and absorbance of merocyanine were also observed during ATP-dependent accumulation of calcium into sarcoplasmic reticulum. These changes are satisfactorily explained by the binding of accumulated calcium to binding sites on the interior of sarcoplasmic reticulum membrane. The small absorbance response of the oxonol dye bis[1,3-dibutylbarbituric acid-(5)]trimethinoxonol to Ca2+ and ATP is qualitatively similar to that of merocyanine 540 and can be readily explained by the same mechanism. We have found no clear evidence that any of the observed dye responses are due to changes in the diffusion potential across the sarcoplasmic reticulum membrane generated by an electrogenic transport mechanism. The possibility is considered that merocyanine and oxonol dyes respond to changes in electrostatic surface potential caused by the binding of cations.

4-Aminobutyrate aminotransferase fluorescence studies

The kinetics of resolution of the pyridoxamine phosphate form of the enzyme 4-aminobutyrate aminotransferase were monitored by fluorescence spectroscopy. 2 mol pyridoxamine phosphate are released/mol enzyme, indicating that two molecules of cofactor are involved in catalysis. The apoprotein is reconstituted by addition of pyridoxal phosphate; the apparent rate constant corresponding to the formation of active species is not a linear function of the concentration of cofactor. A multistep mechanism is proposed for the reconstitution of 4-aminobutyrate aminotransferase. A slow phase of reactivation of the aminotransferase is observed when the apoprotein is allowed to reconstitute in the presence of pyridoxal kinase, ATP and pyridoxal. The enzyme 4-aminobutyrate aminotransferase is a dimeric protein made up of subunits of identical molecular weight. It is characterized by a rotational relaxation time of 110 ns. The dimeric structure does not dissociate into subunits over a wide range of protein concentration (4--0.2 micrometer) at neutral pH.

Photodynamic properties of pyridoxal phosphate bound to cystathionase-gamma-lyase

The cofactor pyridoxal phosphate bound through an aldimine linkage to lysine residues of the enzyme cystathionase (L-Cystathione cysteine-lyase (deaminating), EC 4.4.1.1) is very stable to irradiation with light of 420 nm. The catalytic function of the enzyme remains unaffected indicating that the cofactor is not an efficient photosensitizer of essential amino acid residues. This unusual stability of the cofactor to irradiation can be ascribed to the presence of aldimine linkages as demonstrated by studies conducted on model compounds. The binding of a reversible inhibitor (L-allylglycine) to the catalytic site of the enzyme does not facilitate photooxidation of the cofactor. On the contrary, irradiation of the cofactor in the presence of the inhibitor results in photodestruction of the inhibitor.

Reactivity of the phosphopyridoxal groups of cystathionase

Aminooxyacetate and alpha-amino-gamma-aminooxybutyrate (canaline) react specifically with the P-pyridoxal groups of cystathionase to produce characteristic changes in the absorption and fluorescence properties of the bound cofactor. The increase in fluorescence at 450 nm was used to monitor the reaction. Aminooxyacetate attacks the Schiff base linkage of the enzyme several times faster (k1 = 3700 M-1 min-1 and k2 = 1000 M-1 min-1) than it attacks the aldehydic carbon of free P-pyridoxal (k = 290 M-1 min-1). Similar results were obtained with canaline. The kinetic studies indicate that a Schiff base linkage in the enzyme cystathionase should offer direct kinetic advantage during the reaction between the substrate and the cofactor. It is also shown that the inhibitor L-alpha-gamma-aminobutyrate reacts with bound P-pyridoxal to form free P-pyridoxamine. The rate of formation of P-pyridoxamine parallels the rate of enzyme inactivation.

Nonequivalent binding sites in cystathionase. Nanosecond and steady fluorescence studies

The analogs P-pyridoxyl-L-alanine and P-pyridoxyl-L-homoserine bind to the apoprotein of the enzyme cystathionase and inhibit the reactivation of enzymatic activity after addition of pyridoxyl-5-P. The binding of the inhibitors was monitored by measuring the fluorescence emitted by the P-pyridoxyl moiety at 395 nm (excitation 325 nm). The fluorometric titration results indicate the presence of nonequivalent binding sites in the apoprotein. A model based on two classes of independent binding sites fits the fluorometric data reasonably well. The presence of nonequivalent fluorescent sites in reduced cystathionase was also detected by nanosecond spectroscopy. In contrast to the model compound P-pyridoxyl-epsilon-lysine (tau equals 2.6 ns), the P-pyridoxyl residues of cystathionase display multiexponential fluorescence decay. Two fluorescence lifetimes (tau2 equals 4.1 ns and tau2 equals 15 ns) fit the deconvoluted decay results obtained by pulse fluorimetry. It is proposed that the P-pyridoxyl chromophores of reduced cystathionase have different environments.