Evaluation of eight plasma proteins as candidate blood-based biomarkers for malignant gliomas.

Eight brain-derived proteins were evaluated regarding their potential for further development as a blood-based biomarker for malignant gliomas. Plasma levels for glial fibrillary acidic protein, neurogranin, brain-derived neurotrophic factor, intracellular adhesion molecule 5, metallothionein-3, beta-synuclein, S100 and neuron specific enolase were tested in plasma of 23 patients with high-grade gliomas (WHO grade IV), 11 low-grade gliomas (WHO grade II), and 15 healthy subjects. Compared to the healthy controls, none of the proteins appeared to be specific for glioblastomas. However, the data are suggestive of higher protein levels in gliosarcomas (n = 2), which may deserve further exploration.

Mitotic phosphorylation activates hepatoma-derived growth factor as a mitogen.

BACKGROUND: Hepatoma-derived growth factor (HDGF) is a nuclear protein that is a mitogen for a wide variety of cells. Mass spectrometry based methods have identified HDGF as a phosphoprotein without validation or a functional consequence of this post-translational modification. RESULTS: We found that HDGF in primary mouse aortic vascular smooth muscle cells (VSMC) was phosphorylated. Wild type HDGF was phosphorylated in asynchronous cells and substitution of S103, S165 and S202 to alanine each demonstrated a decrease in HDGF phosphorylation. A phospho-S103 HDGF specific antibody was developed and demonstrated mitosis-specific phosphorylation. HDGF-S103A was not mitogenic and FACS analysis demonstrated a G2/M arrest in HDGF-S103A expressing cells, whereas cells expressing HDGF-S103D showed cell cycle progression. Nocodazole arrest increased S103 phosphorylation from 1.6% to 29% (P = 0.037). CONCLUSIONS: Thus, HDGF is a phosphoprotein and phosphorylation of S103 is mitosis related and required for its function as a mitogen. We speculate that cell cycle regulated phosphorylation of HDGF may play an important role in vascular cell proliferation.

Plasma glial fibrillary acidic protein levels in children with sickle cell disease.

To determine if glial fibrillary acidic protein (GFAP) is associated with brain injury in children with sickle cell disease (SCD), we measured plasma GFAP among cross-sectional groups of unselected children with SCD, subsets of children with SCD and normal brain MRI or MRI evidence of cerebral infarct, healthy pediatric controls, and adults with brain injury. Children with SCD had higher plasma GFAP than healthy pediatric controls (mean concentrations 0.14 ± 0.37 vs. 0.07 ± 0.08 ng/mL; P 5 0.003); also, 16.0% (16/100) of children with SCD and cerebral infarct had GFAP elevations above the 95th percentile of healthy pediatric controls (P 5 0.04). Although not statistically significant, children with SCD and cerebral infarct had more elevated GFAP levels than with SCD and no infarct (16/100, 16.0% vs. 14/168, 8.3%; P 5 0.07). Children with SCD and acute brain ischemia had a higher proportion of elevated GFAP than SCD children with normal MRI (3/6, 50% vs.8.3%; P 5 0.01). GFAP was associated with elevated systolic blood pressure in the preceding year and correlated positively with white blood cell count and negatively with age and performance IQ. Plasma GFAP is elevated among children with SCD and may be associated with subclinical brain injury.

Hemoglobin depletion from plasma: considerations for proteomic discovery in sickle cell disease and other hemolytic processes.

PURPOSE: Hemoglobin (Hb) depletion with nickel affinity chromatography has been shown to increase the number of proteins identified in proteomic studies of erythrocytes, but limited data exist on the application of this technique in depletion of Hb from plasma or serum required for clinical biomarker studies. The aim of this study was to explore the potential of using nickel-beads for Hb depletion of plasma. EXPERIMENTAL DESIGN: Nickel­nitrilotriacetic acid (Ni­NTA) affinity chromatography was used to deplete Hb from hemolyzed plasma samples obtained from children with sickle cell disease (SCD, n=7) and normal human plasma (n=4). Ni­NTA-bound proteins were analyzed by one-dimensional GE, followed by in-gel digestion for characterization using an LTQ-Orbitrap hybrid mass spectrometer. In addition, the loss of two non-Hb-related plasma proteins, thrombospondin1 and L-selectin, by Ni­NTA was determined by ELISA (SCD n=6, non-SCD controls n=2). RESULTS: Ni­NTA resulted in an average 60% decrease in plasma protein concentration, which was not hemolysis dependent. Specifically, Hb (7 peptides) and the top three proteins, -2-macroglobulin (75 peptides), apolipoprotein B-100 (73 peptides), and albumin (42 peptides) were Ni­NTA bound. In addition, using an ELISA assay two non-Hb-associated plasma proteins thrombospondin1 and L-selectin were decreased by Ni-NTA. CONCLUSIONS AND CLINICAL RELEVANCE: Hb depletion with Ni­NTA is effective for Hb removal but is not specific. There is a potential for deleterious depletion of potential biomarkers that may limit the applicability of this method. Consideration of alternate methods of Hb depletion for clinical proteomics may be warranted.

Huntingtin is cleaved by caspases in the cytoplasm and translocated to the nucleus via perinuclear sites in Huntington's disease patient lymphoblasts.

Accumulation of mutant Huntingtin (Htt), especially the N-terminal-cleaved Htt, participates in the pathophysiology of Huntington's disease (HD). It is difficult to elucidate temporal properties of the translocation of "endogenous" Htt using autopsy HD patient brains. Thus, we examined the cell biology of "endogenous" Htt cleavage and nuclear translocation in cultured lymphoblasts of HD patients and controls. Apoptotic stimulation of lymphoblasts elicits caspase-dependent cleavage and selective nuclear translocation of N-terminal portions of Htt. Discrete clusters of the N-terminal Htt accumulate at unique perinuclear sites prior to nuclear translocation. Our findings suggest that caspase cleavage of Htt is cytoplasmic and precedes sorting to specific perinuclear sites followed by nuclear translocation in HD patient tissue.