Origin of Proteinuria as Observed from Qualitative and Quantitative Analysis of Serum and Urinary Proteins

Article information

Child Kidney Dis. 2015;19(2):65-70
Publication date (electronic) : 2015 October 30
doi : https://doi.org/10.3339/chikd.2015.19.2.65
Department of Pediatrics and Child Health Nihon University School of Medicine
Corresponding author: Shori Takahashi, M.D., Ph.D. Department of Pediatrics and Child HealthNihon University School of Medicine.
Received 2015 October 9; Revised 2015 October 15; Accepted 2015 October 20.

Abstract

It is well known that proteins present in the primary urine are reabsorbed in the renal proximal tubules, and that this reabsorption is mediated via the megalin‐cubilin complex and the neonatal Fcγ receptor. However, the reabsorption is also thought to be influenced by an electrostatic interaction between protein molecules and the microvilli of the renal proximal tubules. By analyzing the charge diversity of urinary IgG, we showed that this reabsorption process occurs in a cationic charge-preferential manner. The charge‐selective molecular sieving function of the glomerular capillary walls has long been a target of research since Brenner et al. demonstrated the existence of this function by a differential clearance study by using the anionic dextran sulfate polymer. However, conclusive evidence was not obtained when the study was performed using differential clearance of serum proteins. We noted that immunoglobulin (Ig) A and IgG have similar molecular sizes but distinct molecular isoelectric points. Therefore, we studied the differential clearance of these serum proteins (clearance IgA/clearance IgG) in podocyte diseases and glomerulonephritis. In addition, we studied this differential clearance in patients with Dent disease rather than in normal subjects because the glomerular sieving function is considered to be normal in subjects with Dent disease. Our results clearly showed that the charge-selective barrier is operational in Dent disease, impaired in podocyte disease, and lacking in glomerulonephritis.

Introduction

Proteinuria has long been one of the most important targets of therapy for many kidney diseases. However, only a small number of studies have been performed that analyzed urinary proteins in comparison with serum proteins in glomerular diseases.

Urinary proteins in glomerular diseases are those proteins that pass through the glomerular capillary walls in considerable amounts, and are then eliminated via reabsorption by the renal proximal tubules. Fig. 1A (arrows) shows the path of proteins in primary urine; the proteins pass through the glomerular capillary walls, then attach, and are reabsorbed by the renal proximal tubules. The proteins eliminated by reabsorption are then concentrated and voided as final urinary proteins. On the other hand, in renal tubular diseases, the urinary proteins consist of proteins that pass through the glomerular capillary walls in very small amounts, but are not reabsorbed by the renal proximal tubules, and are concentrated and voided into the final urine (Fig. 1B). It is necessary to understand these processes better in order to elucidate the charge-selective protein sieving function of the glomerular capillary walls.

Fig. 1.

Urinary protein: Proteins that pass through the glomerular capillary walls and then are eliminated via reabsorption by the renal proximal tubules.

Cationic charge-preferential protein reabsorption in renal proximal tubules

The megalin‐cubilin complex has been found to play a central role in protein reabsorption in the proximal tubules, and serves as a multi-ligand receptor [1]. However, another receptor located in the proximal tubules also binds to immunoglobulin G (IgG) (Fig. 2) [2]. This receptor is identical to the neonatal Fcγ receptor (FcRN). FcRN is expressed in the human placenta, and is known to transport IgG from mother to the fetus by means of transcytosis. Recently, several papers have postulated that this FcRN also transports albumin in the proximal tubules for recycling of albumin [3]. However, it has long been hypothesized that a cationic charge-preferential reabsorption mechanism is present in the renal proximal tubules (Fig. 3) [4] because the microvilli of the renal proximal tubular cells are negatively charged and some parts of the filtered proteins are thought to be positively charged because of the acidification of urine in the proximal tubules. To provide evidence in support of this hypothesis, we sought to evaluate the charge diversity of serum and urinary IgG.

Fig. 2.

The megalin-cubulin complex (multi-ligand receptor) and the neonatal Fcγ receptor (FcRN) expressed in renal proximal tubules bind to filtered proteins, leading to reabsorption.

Fig. 3.

Glomerular ultrafiltration is acidified in the renal proximal tubules where the urinary pH falls to around 6. Positively charged serum proteins at this pH may attach to the negatively charged microvilli of the brush border via electrostatic binding.

Discussion

Prior to discussing the results of the present study, it is necessary to understand the principle of isoelectric focusing, as shown in Fig. 4. The isoelectric point (pI) is the pH at which a protein does not carry a net electrical charge. Proteins are composed of amino acids and sugars, which are basic, neutral, or acidic in nature. The pH of the urine falls to 6 in the renal proximal tubules. At this pH, the cationic portion of IgG (pI 8–9) is strongly positively charged, and seems to attach more easily to the negatively charged microvilli of the renal proximal tubules.

Fig. 4.

Proteins indicated by the oval circle are charged positively when pH is neutral or acidic (cationic proteins).

In order to show cationic charge‐preferential protein reabsorption in the renal tubules, we utilized the characteristics of the very broad charge diversity of IgG. As shown in Fig. 5 (square box), the cationic portion of IgG (pI 8–9; indicated by arrow) is present in the serum (S) but absent in the urine (U).

Fig. 5.

Iso-electric focusing immunoblotting analysis of serum and urinary IgG from MCNS and IgAN

IEF: iso-electric focusing, MCNS: minimal change nephrotic syndrome, IgAN: IgA nephritis, S: serum, U: urine.

IgG has been shown to be reabsorbed in the renal proximal tubules by FcRN in vitro. This process is inhibited if the pH of the culture medium is raised (as the cationic charge decreases) [2].

In cases of Dent disease showing proximal tubular proteinuria, the charge diversities of serum and urinary IgGs have been observed to be almost identical (Fig. 6). This indicates that the cationic charge-preferential protein reabsorption mechanism is not functional in Dent disease. This difference in the charge diversities of urinary IgG in glomerular diseases compared to those in renal tubular diseases is apparent. The cationic portion of IgG that is absent in glomerular diseases (upper arrow), but is present in renal tubular diseases (lower arrow). This suggests that the cationic portion of IgG is reabsorbed in the renal proximal tubules only with the renal proximal tubular function intact (Fig. 7) [5].

Fig. 6.

The charge diversities of serum and urinary immunoglobulin G (IgG) are almost identical.

Fig. 7.

The differences in charge diversity of urinary immunoglobulin G (IgG) between glomerular and renal tubular diseases.

In a patient with lupus membranous nephropathy (LMN) with extremely severe proteinuria, the charge diversity between serum and urinary IgG did not show any difference (Fig. 8, upper arrows). However, during remission, the cationic part of IgG in the urine became predominantly faint (Fig. 8, lower arrows). This indicates that the reabsorption of IgG may be a saturable process [5].

Fig. 8.

Reabsorption of cationic immunoglobulin G (IgG) is a saturable process.

LMN: Lupus membranous nephropathy, S: serum, U: urine.

Charge selectivity index showed differences in the glomerular charge sieving function between healthy subjects, patients with podocyte disease, and patients with glomerulonephritis

Next, we investigated the charge selectivity of the glomerular capillary walls by analyzing serum and urinary IgA and IgG. IgA has a Stokes‐Einstein (S-E) radius of 61 Å and low pI (3.5–5.5), while IgG has a Stokes‐Einstein radius of 49–60 Å and high pI (4.5–9) (Fig. 9A). Therefore, the molecules have similar tertiary structure and S-E radius, but distinct isoelectric points. Fig. 9B shows 2-dimensional (2D) electrophoresis [6] isoelectric focusing (IEF) for the horizontal dimension, and sodium dodecyl sulfate (SDS) polyacrylamide gel electrophoresis for the vertical dimension), followed by immunoblotting of IgA and IgG (2D immunoblotting of IgA and IgG). This figure clearly illustrates the distinct difference in molecular charge between IgA and IgG.

Fig. 9.

A) Molecular structure and charge of immunoglobulin [7] and immunoglobulin G (IgG). B) 2-dimensional immunoblotting of IgG and IgA of serum and urine samples obtained from steroid-responsive nephrotic syndrome.

Fig. 10 shows the 2D immunoblotting of serum and urinary IgA and IgG in patients with steroid‐sensitive nephrotic syndrome (SSNS; Fig. 10A) and IgA nephropathy (IgAN; Fig. 10B). It is obvious that the density of IgA in the urine of patient with SSNS is much weaker than that of IgAN in comparison with that of urinary IgG in both diseases. These results indicate that the fractional clearance of IgA to IgG could serve as a charge selectivity index (CSI) of the glomerular capillary walls (Fig. 10C) [7].

Fig. 10.

Two-dimensional immunoblotting of serum and urinary immunoglobulin A [7] and immunoglobulin G (IgG). A) Steroid-sensitive nephrotic syndrome (SSNS). B) IgA nephropathy (IgAN). C) Formula of the charge selectivity index (CSI).

However, it was difficult to determine how to evaluate the CSI of healthy subjects. Thus, we chose to use the CSI of patients with Dent disease instead of healthy subjects, since patients with Dent disease are considered to have a normal glomerular sieving function, but defective proximal tubular protein reabsorption [8]. Therefore, the final urine of patients with Dent disease could be considered a concentrate of the primary urine eliminating the influence of reabsorption through the renal proximal tubules.

We investigated the differences in charge selectivity in the glomerular capillary walls using CSI (Fig. 10C). The CSI was investigated in eight patients with Dent disease (Group A), in 40 patients with podocyte disease (Group B: SSNS 35 patients, focal segmental glomerulosclerosis 4 patients, and Finnish type congenital nephrotic syndrome 1 patient), and in 75 patients with chronic glomerulonephritis (Group C: IgAN 41 patients, purpura nephritis 21 patients, membranoproliferative glomerulonephritis 5 patients, and Alport syndrome 8 patients). The results showed a statistically significant difference in CSI between each group (Table 1 and Fig. 11) [7].

Charge selectivity index (CSI) in Dent disease, podocyte disease, and glomerulonephritis

Fig. 11.

Comparison of the charge selectivity index (CSI) among three disease groups. A) Dent disease group. B) Podocyte disease group. C) Chronic glomerulonephritis group.

Conclusion

The cationic portion of IgG is reabsorbed in the normal renal proximal tubules, in a cationic charge‐preferential manner, and the reabsorption of cationic IgG seems to be a saturable process. The charge‐selective protein sieving function is operational in healthy subjects, impaired in podocyte disease, and is lacking in patients affected by glomerulonephritis.

References

1. Christensen EI, Birn H. Megalin and cubilin: synergistic endocytic receptors in renal proximal tubule. American journal of physiology Renal physiology 2001;280(4):F562–573.
2. Kobayashi N, Suzuki Y, Tsuge T, Okumura K, Ra C, Tomino Y. FcRn-mediated transcytosis of immunoglobulin G in human renal proximal tubular epithelial cells. American journal of physiology Renal physiology 2002;282(2):F358–365.
3. Tenten V, Menzel S, Kunter U, Sicking EM, van Roeyen CR, Sanden SK, et al. Albumin is recycled from the primary urine by tubular transcytosis. Journal of the American Society of Nephrology : JASN 2013;24(12):1966–1980.
4. Maack T, Johnson V, Kau ST, Figueiredo J, Sigulem D. Renal filtration, transport, and metabolism of low-molecular-weight proteins: a review. Kidney international 1979;16(3):251–270.
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6. Gorg A, Postel W, Gunther S, Friedrich C. Horizontal two-dimensional electrophoresis with immobilized pH gradients using PhastSystem. Electrophoresis 1988;9(1):57–59.
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8. Christensen EI, Devuyst O, Dom G, Nielsen R, Van der Smissen P, Verroust P, et al. Loss of chloride channel ClC-5 impairs endocytosis by defective trafficking of megalin and cubilin in kidney proximal tubules. Proceedings of the National Academy of Sciences of the United States of America 2003;100(14):8472–8477.

Article information Continued

Fig. 1.

Urinary protein: Proteins that pass through the glomerular capillary walls and then are eliminated via reabsorption by the renal proximal tubules.

Fig. 2.

The megalin-cubulin complex (multi-ligand receptor) and the neonatal Fcγ receptor (FcRN) expressed in renal proximal tubules bind to filtered proteins, leading to reabsorption.

Fig. 3.

Glomerular ultrafiltration is acidified in the renal proximal tubules where the urinary pH falls to around 6. Positively charged serum proteins at this pH may attach to the negatively charged microvilli of the brush border via electrostatic binding.

Fig. 4.

Proteins indicated by the oval circle are charged positively when pH is neutral or acidic (cationic proteins).

Fig. 5.

Iso-electric focusing immunoblotting analysis of serum and urinary IgG from MCNS and IgAN

IEF: iso-electric focusing, MCNS: minimal change nephrotic syndrome, IgAN: IgA nephritis, S: serum, U: urine.

Fig. 6.

The charge diversities of serum and urinary immunoglobulin G (IgG) are almost identical.

Fig. 7.

The differences in charge diversity of urinary immunoglobulin G (IgG) between glomerular and renal tubular diseases.

Fig. 8.

Reabsorption of cationic immunoglobulin G (IgG) is a saturable process.

LMN: Lupus membranous nephropathy, S: serum, U: urine.

Fig. 9.

A) Molecular structure and charge of immunoglobulin [7] and immunoglobulin G (IgG). B) 2-dimensional immunoblotting of IgG and IgA of serum and urine samples obtained from steroid-responsive nephrotic syndrome.

Fig. 10.

Two-dimensional immunoblotting of serum and urinary immunoglobulin A [7] and immunoglobulin G (IgG). A) Steroid-sensitive nephrotic syndrome (SSNS). B) IgA nephropathy (IgAN). C) Formula of the charge selectivity index (CSI).

Fig. 11.

Comparison of the charge selectivity index (CSI) among three disease groups. A) Dent disease group. B) Podocyte disease group. C) Chronic glomerulonephritis group.

Table 1.

Charge selectivity index (CSI) in Dent disease, podocyte disease, and glomerulonephritis

Group Disease n U Pro/Cr meam (±SEM) CSI mean (±SD)
Dent disease (group A) Dent disease 8 ND 0.16 (0.06)
Podocyte disease (group B) Steroid sensitive nephrotic syndrome 35 18.24 (3.12) 0.42 (0.31)
Focalsegm entalgbm bscrerosis 4 27.1 (ND)
Finnish type congenita Inephrotic syndrome 1 15.5 (ND)
Chronic Glomerulonehritis (group C) IgA nephropathy 41 1.02 (0.13) 1.12 (0.25)
Purpura nephritis 21 7.29 (3.81)
Membranoproliferative glomerulonephritis 5 0.81 (ND)
Alport syndrome 8 1.19 (0.39)