Absolute Quantification of Human Serum Albumin Isoforms by Internal Calibration Based on a Top-Down LC-MS Approach

Bibliographic info

  • Authors: Roy Lakis§, François-Ludovic Sauvage§, Emilie Pinault, Pierre Marquet, Franck Saint-Marcoux, Souleiman El Balkhi (§ equal contribution)
  • Journal: Analytical Chemistry, 2024, vol. 96, pp. 746–755
  • DOI: 10.1021/acs.analchem.3c03933
  • Institution: P&T UMR1248 INSERM / CHU Limoges
  • File: raw/my_work/lakis-et-al-2024-...pdf

Key question

Can a top-down LC-MS method with an equine myoglobin internal standard provide reliable absolute quantification of HSA isoforms in clinical plasma samples, with sufficient accuracy and precision for use as a clinical biomarker assay?

Methods

  • Sample type: Human plasma / serum (clinical samples + spiked standards)
  • Technique: Top-down LC-HR-MS; Top-down proteomics
  • Internal standard: Equine myoglobin (Mb) — dual purpose: (1) mass recalibration per sample, (2) absolute quantification anchor
  • Sample prep: 1:50 dilution in 0.9% NaCl + Mb (4 g/L final in diluted sample); C4 column
  • Two quantification approaches tested:
    1. Deconvoluted peak integration (DPI) — from the deconvoluted mass spectrum
    2. Extracted Ion Chromatogram (XIC) — from raw m/z data

Main findings

  1. Myoglobin IS solves the mass accuracy problem: conventional top-down deconvolution has 1–5 Da mass errors; Mb IS enables systematic per-sample mass recalibration → extremely low mass deviations
  2. 8 HSA isoforms quantified with specific calibration curves showing good linearity (deconvoluted peak approach)
  3. Isoform-dependent ionization: HSA isoforms do not ionize equally → using a single generic HSA standard underestimates some isoforms. An enriched isoform calibration solution is required for accurate absolute quantification
  4. Good repeatability, reproducibility, accuracy — CV acceptable for clinical use
  5. Better sensitivity than routine biochemical assays for low albumin samples (relevant in advanced liver disease where albumin is severely depleted)
  6. Workflow: relatively simple; high-throughput compatible; aimed at clinical translation

PTMs reported

ProteinIsoformModificationΔmass (Da)Notes
HSANativeNone0Reference isoform
HSAHSA+CYSCysteinylation Cys34+119
HSAHSA+GLYCGlycation (Lys)+162
HSAHSA+CYS+GLYCCYS + GLYC+281
HSAHSA+2GLYCDouble glycation+324
HSAHSA+CYS+2GLYCCYS + 2×GLYC+443
HSAHSA-DAN-term truncation−115
HSAHSA-LC-term truncationvariable

Clinical context

HSA isoforms as biomarkers of diabetes, kidney disease, and liver disease. This method enables quantitative (g/L) isoform profiling — prior methods only gave relative abundances (%). Absolute quantification is critical for clinical cut-off definition and multicenter deployment.

Limitations

  • Enriched isoform calibration solution required (adds complexity)
  • XIC approach not superior to DPI; DPI preferred
  • Validation focused on methodological performance; clinical cohort data not in this paper (done in el-balkhi-2025)

Connections

My notes

This is the foundational methods paper for ALBOM. Everything in el-balkhi-2025 rests on this validated method. Key innovation: isoform-dependent ionization is a genuine calibration challenge that was properly solved here by using enriched isoform standards rather than a single commercial HSA calibrator. This paper should be cited in any clinical or regulatory context for the ALBOM method.