Procathepsin E is highly abundant but minimally active in pancreatic ductal adenocarcinoma tumors.

The cathepsin family of lysosomal proteases is increasingly being recognized for their altered expression in cancer and role in facilitating tumor progression. The aspartyl protease cathepsin E is overexpressed in several cancers and has been investigated as a biomarker for pancreatic ductal adenocarcinoma (PDAC). Here we show that cathepsin E expression in mouse PDAC tumors is increased by more than 400-fold when compared to healthy pancreatic tissue. Cathepsin E accumulates over the course of disease progression and accounts for more than 3% of the tumor protein in mice with end-stage disease. Through immunoblot analysis we determined that only procathepsin E exists in mouse PDAC tumors and cell lines derived from these tumors. By decreasing the pH, this procathepsion E is converted to the mature form, resulting in an increase in proteolytic activity. Although active site inhibitors can bind procathepsin E, treatment of PDAC mice with the aspartyl protease inhibitor ritonavir did not decrease tumor burden. Lastly, we used multiplex substrate profiling by mass spectrometry to identify two synthetic peptides that are hydrolyzed by procathepsin E near neutral pH. This work represents a comprehensive analysis of procathepsin E in PDAC and could facilitate the development of improved biomarkers for disease detection.

Beta 2-microglobulin deficient mice catabolize IgG more rapidly than FcRn- alpha-chain deficient mice.

FcRn, a nonclassical MHC-I protein bound to beta 2-microglobulin (beta 2m), diverts IgG and albumin from an intracellular degradative fate, prolonging the half-lives of both. While knockout mouse strains lacking either FcRn-alpha-chain (AK) or beta 2m (BK) show much shorter half-lives of IgG and albumin than normal mice, the plasma IgG half-life in the BK and AK strains is different, being shorter in the BK strain. Since beta 2m does not affect the IgG production rate, we tested whether an additional beta 2m-associated mechanism protects IgG from catabolism. First, we compared the fractional disappearance rate in plasma of an intravenous dose of radioiodinated IgG in a mouse strain deficient in both FcRn-alpha-chain and beta 2m (ABK), in the two parental knockout strains (AK and BK), and in the background wild-type (WT) strain. We found that IgG survived longer in the beta 2m-expressing AK strain than in the beta 2m-lacking ABK and BK strains, whereas the IgG half-lives between the ABK and BK strains were identical. Then we compared endogenous concentrations of four typical plasma proteins among the four strains and found that steady-state plasma concentrations of both IgG and albumin were higher in the AK strain than in either the BK or the ABK strain. These results suggest that a beta 2m-associated effect other than FcRn prolongs the survival of both IgG and albumin, although leaky gene transcription in the AK strain cannot be ruled out.

Accelerated transferrin degradation in HFE-deficient mice is associated with increased transferrin saturation.

HFE, a major histocompatibility complex class I-related protein, is implicated in the iron overload disease, hereditary hemochromatosis. Whereas patients with hereditary hemochromatosis have low serum transferrin levels, little is known about transferrin turnover in HFE deficiency states. We injected mice intravenously with radioiodinated transferrin and compared plasma transferrin decay and steady-state endogenous transferrin concentration in the plasma between HFE-deficient and wild-type C57BL/6 mouse strains. HFE-deficient mice degraded transferrin faster than normal (P < 0.001) and had lower plasma transferrin concentrations (P < 0.001). Both HFE-deficient and wild-type mice were then fed diets with 3 different iron concentrations that we designated deficient (2-5 mg/kg of iron), control (0.2 g/kg), and overload (20 g/kg) for 6 wk immediately after weaning to create a range of serum iron concentrations and resultant transferrin saturations ranging from 16 to 78%. We found an inverse correlation between transferrin saturation and transferrin half-life (P < 0.0001, r = -0.839) for both HFE-deficient and wild-type mice, which suggests that HFE does not have a direct effect on transferrin catabolism; rather, HFE may influence transferrin half-life indirectly through its effect on transferrin saturation, which in turn enhances transferrin decay in HFE-deficient mice.

Perspective-- FcRn transports albumin: relevance to immunology and medicine.

Recent evidence validates a forgotten 40-year-old hypothesis: the MHC-related Fc receptor for IgG (FcRn) protects albumin from intracellular catabolic degradation, as it does for IgG, accounting for the uniquely long half-lives of both molecules and explaining their direct concentration-catabolism relationships. Albumin and IgG bind to FcRn at low pH but not at physiological pH. These two ligands bind independently of one another by distinctive mechanisms and to different surfaces of the receptor. Kinetic studies of FcRn-deficient mice indicate that, at steady-state, FcRn salvages from the degradative pathway a similar amount of albumin as is produced by mice and almost four-times more IgG than is produced. Thirty-fivefold more albumin than IgG molecules are protected from degradation by FcRn per unit time. It can be inferred that FcRn is expressed in nearly all cells. This receptor, originally described as transporting IgG from the mother to the fetus or neonate, now has a wider role central to the homeostatic regulation and conservation of both albumin and IgG throughout life.

Albumin binding to FcRn: distinct from the FcRn-IgG interaction.

The MHC-related Fc receptor for IgG (FcRn) protects albumin and IgG from degradation by binding both proteins with high affinity at low pH in the acid endosome and diverting both from a lysosomal pathway, returning them to the extracellular compartment. Immunoblotting and surface plasmon resonance studies show that both IgG and albumin bind noncooperatively to distinct sites on FcRn, that the affinity of FcRn for albumin decreases approximately 200-fold from acidic to neutral pH, and that the FcRn-albumin interaction shows rapid association and dissociation kinetics. Isothermal titration calorimetry shows that albumin binds FcRn with a 1:1 stoichiometry and the interaction has hydrophobic features as evidenced by a large positive change in entropy upon binding. Our results suggest that the FcRn-albumin interaction has unique features distinct from FcRn-IgG binding despite the overall similarity in the pH-dependent binding mechanism by which both ligands are protected from degradation.

Familial hypercatabolic hypoproteinemia caused by deficiency of the neonatal Fc receptor, FcRn, due to a mutant beta2-microglobulin gene.

Two siblings, products of a consanguineous marriage, were markedly deficient in both albumin and IgG because of rapid degradation of these proteins, suggesting a lack of the neonatal Fc receptor, FcRn. FcRn is a heterodimeric receptor composed of a nonclassical MHC class I alpha-chain and beta(2)-microglobulin (beta(2)m) that binds two ligands, IgG and albumin, and extends the catabolic half-lives of both. Eight relatives of the siblings were moderately IgG-deficient. From sera archived for 35 years, we sequenced the two siblings' genes for the heterodimeric FcRn. We found that, although the alpha-chain gene sequences of the siblings were normal, the beta(2)m genes contained a single nucleotide transversion that would mutate a conserved alanine to proline at the midpoint of the signal sequence. Concentrations of soluble beta(2)m and HLA in the siblings' sera were <1% of normal. Transfection assays of beta(2)m-deficient cultured cells with beta(2)m cDNA indicated that the mutant beta(2)m supported <20% of normal expression of beta(2)m, MHC class I, and FcRn proteins. We concluded that a beta(2)m gene mutation underlies the hypercatabolism and reduced serum levels of albumin and IgG in the two siblings with familial hypercatabolic hypoproteinemia. This experiment of nature affirms our hypothesis that FcRn binds IgG and albumin, salvages both from a degradative fate, and maintains their physiologic concentrations.

The major histocompatibility complex-related Fc receptor for IgG (FcRn) binds albumin and prolongs its lifespan.

The inverse relationship between serum albumin concentration and its half-life suggested to early workers that albumin would be protected from a catabolic fate by a receptor-mediated mechanism much like that proposed for IgG. We show here that albumin binds FcRn in a pH dependent fashion, that the lifespan of albumin is shortened in FcRn-deficient mice, and that the plasma albumin concentration of FcRn-deficient mice is less than half that of wild-type mice. These results affirm the hypothesis that the major histocompatibility complex-related Fc receptor protects albumin from degradation just as it does IgG, prolonging the half-lives of both.