Helle Naver

Traveling‐wave ion mobility mass spectrometry of protein complexes: accurate calibrated collision cross‐sections of human insulin oligomers

RATIONALE The collision cross-section (Ω) of a protein or protein complex ion can be measured using traveling-wave (T-wave) ion mobility (IM) mass spectrometry (MS) via calibration with compounds of known Ω. The T-wave Ω-values depend strongly on instrument parameters and calibrant selection. Optimization of instrument parameters and calibration standards are crucial for obtaining accurate T-wave Ω-values. METHODS Human insulin and the fast-acting insulin aspart under native-like conditions (ammonium acetate, physiological pH) were analyzed on Waters SYNAPT G1 and G2 HDMS instruments. The calibrated T-wave Ω-values of insulin monomer, dimer, and hexamer ions were measured using many different combinations of denatured and native-like calibrants (masses between 2.85 and 256 kDa) and T-wave conditions. Drift-tube Ω-values were obtained on a modified SYNAPT G1. RESULTS Insulin T-wave Ω-values were measured at 26 combinations of T-wave velocity and amplitude. Optimal sets of calibrants were identified that yield Ω-values with minimal dependence on T-wave conditions and calibration plots with high R(2)-values. The T-wave Ω-values determined under conditions satisfying these criteria had absolute errors <2%. Structural differences between human insulin and fast-acting insulin aspart were probed with IM-MS. Insulin aspart monomers have increased flexibility, while hexamers are more compact than human insulin. CONCLUSIONS Accurate T-wave Ω-values that are indistinguishable from drift-tube values are obtained when using (1) native-like calibrants with masses that closely bracket that of the analyte, (2) T-wave velocities that maximize the R(2) of the calibration plot for those calibrants, and (3) at least three replicates at T-wave velocities that yield calibration plots with high R(2).

Traveling-wave ion mobility mass spectrometry of protein complexes

RATIONALE The collision cross-section (Ω) of a protein or protein complex ion can be measured using traveling-wave (T-wave) ion mobility (IM) mass spectrometry (MS) via calibration with compounds of known Ω. The T-wave Ω-values depend strongly on instrument parameters and calibrant selection. Optimization of instrument parameters and calibration standards are crucial for obtaining accurate T-wave Ω-values. METHODS Human insulin and the fast-acting insulin aspart under native-like conditions (ammonium acetate, physiological pH) were analyzed on Waters SYNAPT G1 and G2 HDMS instruments. The calibrated T-wave Ω-values of insulin monomer, dimer, and hexamer ions were measured using many different combinations of denatured and native-like calibrants (masses between 2.85 and 256 kDa) and T-wave conditions. Drift-tube Ω-values were obtained on a modified SYNAPT G1. RESULTS Insulin T-wave Ω-values were measured at 26 combinations of T-wave velocity and amplitude. Optimal sets of calibrants were identified that yield Ω-values with minimal dependence on T-wave conditions and calibration plots with high R(2)-values. The T-wave Ω-values determined under conditions satisfying these criteria had absolute errors <2%. Structural differences between human insulin and fast-acting insulin aspart were probed with IM-MS. Insulin aspart monomers have increased flexibility, while hexamers are more compact than human insulin. CONCLUSIONS Accurate T-wave Ω-values that are indistinguishable from drift-tube values are obtained when using (1) native-like calibrants with masses that closely bracket that of the analyte, (2) T-wave velocities that maximize the R(2) of the calibration plot for those calibrants, and (3) at least three replicates at T-wave velocities that yield calibration plots with high R(2).

Changes in Glucose and Fat Metabolism in Response to the Administration of a Hepato-Preferential Insulin Analog

Endogenous insulin secretion exposes the liver to three times higher insulin concentrations than the rest of the body. Because subcutaneous insulin delivery eliminates this gradient and is associated with metabolic abnormalities, functionally restoring the physiologic gradient may provide therapeutic benefits. The effects of recombinant human insulin (HI) delivered intraportally or peripherally were compared with an acylated insulin model compound (insulin-327) in dogs. During somatostatin and basal portal vein glucagon infusion, insulin was infused portally (PoHI; 1.8 pmol/kg/min; n = 7) or peripherally (PeHI; 1.8 pmol/kg/min; n = 8) and insulin-327 (Pe327; 7.2 pmol/kg/min; n = 5) was infused peripherally. Euglycemia was maintained by glucose infusion. While the effects on liver glucose metabolism were greatest in the PoHI and Pe327 groups, nonhepatic glucose uptake increased most in the PeHI group. Suppression of lipolysis was greater during PeHI than PoHI and was delayed in Pe327 infusion. Thus small increments in portal vein insulin have major consequences on the liver, with little effect on nonhepatic glucose metabolism, whereas insulin delivered peripherally cannot act on the liver without also affecting nonhepatic tissues. Pe327 functionally restored the physiologic portal–arterial gradient and thereby produced hepato-preferential effects.

Kinetic Evidence for the Sequential Association of Insulin Binding Sites 1 and 2 to the Insulin Receptor and the Influence of Receptor Isoform.

Through binding to and signaling via the insulin receptor (IR), insulin is involved in multiple effects on growth and metabolism. The current model for the insulin-IR binding process is one of a biphasic reaction. It is thought that the insulin peptide possesses two binding interfaces (sites 1 and 2), which allow it to bridge the two alpha-subunits of the insulin receptor during the biphasic binding reaction. The sequential order of the binding events involving sites 1 and 2, as well as the molecular interactions corresponding to the fast and slow binding events, is still unknown. In this study we examined the series of events that occur during the binding process with the help of three insulin analogues: insulin, an analogue mutated in site 2 (B17A insulin), and an analogue in which part of site 1 was deleted (Des A1-4 insulin), both with and without a fluorescent probe attached. The binding properties of these analogues were tested using two soluble Midi IR constructs representing the two naturally occurring isoforms of the IR, Midi IR-A and Midi IR-B. Our results showed that in the initial events leading to Midi IR-insulin complex formation, insulin site 2 binds to the IR in a very fast binding event. Subsequent to this initial fast phase, a slower rate-limiting phase occurs, consistent with a conformational change in the insulin-IR complex, which forms the final high-affinity complex. The terminal residues A1-A4 of the insulin A-chain are shown to be important for the slow binding phase, as insulin lacking these amino acids is unable to induce a conformational change of IR and has a severely impaired binding affinity. Moreover, differences in the second phase of the binding process involving insulin site 1 between the IR-A and IR-B isoforms suggest that the additional amino acids encoded by exon 11 in the IR-B isoform influence the binding process.