Serum lipoprotein(a) concentrations and apolipoprotein(a) phenotypes in hemodialysis,chronic ambulatory peritoneal dialysis and post-transplant patients

Serum lipoprotein(a) [Lp(a)] concentrations and apolipoprotein(a) apo(a) phenotypes were determined in 81 hemodialysis (HD) patients, 37 chronic ambulatory peritoneal dialysis (CAPD) patients, 25 post-transplant patients and 99 healthy subjects as the reference group. The CAPD patients had significantly higher serum Lp(a) concentration than HD patients, but both had significantly increased Lp(a) levels as compared with the reference group and post-transplant patients. When all studied groups were divided into two subgroups with at least one low molecular weight (LMW) isoform and with only one high molecular weight (HMW) isoform, they presented a similar distribution. (Pearson's chi-squared = 2,78; df = 3; p = NS). The median serum Lp(a) levels were significantly increased with HMW class versus the reference group and post-transplant patients. In CAPD patients, the LMW phenotypes showed significantly increased median serum Lp(a) concentrations versus the reference group, but they were not statistically elevated in HD patients. In the post-transplant patients, LMW and HMW phenotypes did not differ as compared to the reference group. The elevated Lp(a) levels in HD and CAPD groups were explained by apo(a) type-specific, but not by differences in, isoform frequencies. We conclude that HD and CAPD patients had increased Lp(a) levels compared with the reference group, whereas elevated Lp(a) concentrations were observed mainly in patients with HMW apo(a) phenotypes. Patients after renal transplantation showed a correction of Lp(a) levels mainly in HMW phenotypes. The LMW status corresponding to high Lp(a) levels and apo(a) isoforms could be used together with Lp(a) levels with other risk factors to assess in uremic patients the predisposition to coronary artery disease.     

Impact of apolipoprotein(a) phenotypes on long-term renal transplant survival

The long-term success of renal transplantation is limited because of chronic rejection (CR), which shows histologic parallels to atherosclerosis. Lipoprotein(a) [Lp(a)] is an independent risk factor for atherosclerosis, but its role in CR has not been investigated. Plasma levels of Lp(a) are determined mainly by the inherited isoform (phenotype) of apolipoprotein(a) [apo(a)] and show an inverse correlation with the molecular weight of apo(a). Apo(a) isoforms were identified in frozen sera of 327 patients who received a renal transplant during 1982 to 1992. Long-term graft survival in recipients with high molecular weight (HMW) or low molecular weight (LMW) apo(a) phenotypes were compared retrospectively. Mean (95% confidence interval) transplant survival was 12.8 yr (range, 11.9 to 13.6 yr) in patients with HMW and 11.9 yr (range, 10.8 to 13.1 yr) in patients with LMW apo(a) phenotypes (P = 0.2065). In patients who were 35 yr or younger at the time of transplantation, mean transplant survival was more than 3 yr longer in recipients with HMW apo(a) phenotypes compared with those with LMW apo(a) phenotypes (13.2 yr [range, 12.1 to 14.4 yr] versus 9.9 yr (range, 8.5 to 11.5 yr); P = 0.0156). In a Cox's proportional hazards regression model, the presence of LMW phenotypes-but not gender, immunosuppression, or HLA mismatches-in young patients was associated with a statistically significant risk of CR (P = 0.0434). These retrospective data indicate that young renal transplant recipients with LMW apo(a) phenotypes have a significantly shorter long-term graft survival, regardless of the number of HLA mismatches, gender, or immunosuppressive treatment.     

Lipoprotein(a) serum concentrations and apolipoprotein(a) phenotypes in mild and moderate renal failure

High lipoprotein(a) (Lp(a)) serum concentrations and the underlying apolipoprotein(a) (apo(a)) phenotypes are risk factors for cardiovascular disease in the general population as well as in patients with renal disease. Lp(a) concentrations are markedly elevated in patients with end-stage renal disease. However, nothing is known about the changes of Lp(a) depending on apo(a) size polymorphism in the earliest stages of renal impairment. In this study, GFR was measured by iohexol technique in 227 non-nephrotic patients with different degrees of renal impairment and was then correlated with Lp(a) serum concentrations stratified according to low (LMW) and high (HMW) molecular weight apo(a) phenotypes. Lp(a) increased significantly with decreasing GFR. Such an increase was dependent on apo(a) phenotype. Only renal patients with HMW apo(a) phenotypes expressed higher median Lp(a) concentrations, i.e., 6.2 mg/dl at GFR >90 ml/min per 1.73 m2, 14.2 at GFR 45 to 90 ml/min per 1.73 m2, and 18.0 mg/dl at GFR <45 ml/min per 1.73 m2. These values were markedly different when compared with apo(a) phenotype-matched control subjects who had a median level of 4.4 mg/dl (ANOVA, linear relationship, P < 0.001). In contrast, no significant differences were observed at different stages of renal function in patients with LMW apo(a) phenotypes when compared with phenotype-matched control subjects. The elevation of Lp(a) was independent of the type of primary renal disease and was not related to the concentration of C-reactive protein. Multiple linear regression analysis found that the apo(a) phenotype and GFR were significantly associated with Lp(a) levels. Non-nephrotic-range proteinuria modified the association between GFR and Lp(a) levels. In summary, an increase of Lp(a) concentrations, compared with apo(a) phenotype-matched control subjects, is seen in non-nephrotic patients with primary renal disease even in the earliest stage when GFR is not yet subnormal. This change is found only in subjects with HMW apo(a) phenotypes, however.     

Apolipoprotein(a) phenotype, albumin clearance, and plasma levels of lipoprotein(a) in peritoneal dialysis

This cross-sectional study was undertaken to examine the relationship between plasma lipoprotein(a) [Lp(a)] level and peritoneal dialysis (PD) albumin clearance while controlling for the influence of the apolipoprotein(a) [apo(a)] phenotype. Plasma Lp(a) level, PD albumin clearance, and apo(a) phenotype (high vs. low molecular weight, HMW vs. LMW) were determined in 54 PD patients. Apo(a) phenotypes were 24 LMW and 30 HMW. The plasma Lp(a) level was high (> 65 nmol/l) in 17 of 24 patients with LMW phenotype versus 2 of 30 with HMW phenotype (chi2, p < 0.01). Spearman correlation coefficients of Lp(a) with PD, urine, and total albumin clearances were -0.05 (p = 0.74), -0.04 (p = 0.80), and -0.09 (p = 0.51), respectively. The apo(a) isoform size was the only significant predictor of Lp(a) in multivariate analysis. In this study, there was no association between PD albumin clearance and Lp(a) level. The association between apo(a) phenotype and Lp(a) level is in keeping with studies in the general population. There is a strong genetic influence on Lp(a) level in PD patients.     

Lipoprotein(a)-associated atherothrombotic risk in hemodialysis patients

BACKGROUND: Hemodialysis patients show a considerably higher risk of atherothrombotic disease than the general population. We investigated both lipoprotein(a) [Lp(a)] plasma levels and apolipoprotein(a) [apo(a)] phenotypes in relation to occurrence of atherothrombotic events in hemodialysis patients compared with subjects showing a normal kidney function. Methods: Lp(a) levels and apo(a) isoforms were determined in 118 hemodialysis patients, including 59 with prior atherothrombotic events, and in 182 subjects with normal creatinine clearance, including 82 who experienced a prior atherothrombotic event. Results: Lp(a) levels in hemodialysis patients (median; 20 mg/dl) were higher (p < 0.01) than in age- and sex-matched subjects with normal renal function without a history of atherothrombosis (11.3 mg/dl). Among hemodialysis patients, median Lp(a) levels were higher in subjects with than in those without prior atherothrombosis (34 vs. 15 mg/dl, p < 0.05). In hemodialysis patients and in subjects without nephropathy, the percentage of low-molecular-weight apo(a) phenotypes were significantly higher in patients with than in those without a history of prior atherothrombotic events (56.9% vs. 33.9%, p < 0.05; 62.2% vs. 25%, p < 0.00001,respectively). Stepwise regression analysis indicated that the presence of at least one apo(a) isoform of low molecular weight was an independent predictor of atherothrombosis in hemodialysis patients (p < 0.05). Conclusions: Elevated Lp(a) plasma levels appear to be associated with atherothrombosis, independent of their origin due to genetic factors or related to the impaired kidney function. Low-molecular-weight apo(a) isoforms are reliable genetic markers of atherothrombosis both in patients with impaired kidney function and in subjects without nephropathy.     

Lipids and lipoprotein(a) as risk factors for vascular disease in patients on renal replacement therapy

A large cohort of patients on renal replacement therapy werescreened for the presence of symptomatic arterial disease affectingthe coronary, cerebral or peripheral circulations. Ninety-twoof 325 patients were found to have vascular disease. Those withvascular disease had significantly higher median lipoprotein(a)[Lp(a)] levels than those without (38.4 vs 14.2 mg/dl, P<0.001),with a preponderance of Lp(a) levels greater than 30 mg/dl (58%vs 25% P<0.001). Apolipoprotein(a) [apo(a)] isoform distributionwas similar between the groups, but those with vascular diseasehad higher Lp(a) levels in the S2, S3/S4 and S4 isoform types.Comparison of 76 matched pairs of patients confirmed elevatedLp(a) levels in those with vascular disease. These patientsalso had significantly higher total cholesterol (6.66 vs 6.02mmol/l) and low-density lipoprotein cholesterol (4.49 vs 3.86mmol/l). Only Lp(a) was independently associated with vasculardisease (P=0.02). Elevated Lp(a) levels are significantly associatedwith the presence of vascular disease in patients on renal replacementtherapy and may constitute another risk factor for the developmentof such disease in these patients.     

The apolipoprotein(a) size polymorphism is associated with nephrotic syndrome

BACKGROUND: The atherogenic serum lipoprotein(a) [Lp(a)] is significantly elevated in patients with nephrotic syndrome. The underlying mechanism for this elevation is poorly understood. METHODS: We investigated in 207 patients with nondiabetic nephrotic syndrome and 274 controls whether the apolipoprotein(a) [apo(a)] kringle-IV repeat polymorphism explains the elevated Lp(a) levels in these patients. RESULTS: Patients showed a tremendous elevation of Lp(a) concentrations when compared to controls (mean 60.4 vs. 20.0 mg/dL and median 29.8 vs. 6.4 mg/dL, P < 0.0001). Primary and secondary causes contributed to this elevation. The primary causes became apparent by a markedly elevated number of low-molecular-weight apo(a) phenotypes which are usually associated with high Lp(a) levels. This frequency was 35.7% in patients compared to only 24.8% in controls (P= 0.009). In addition, secondary causes by the pathogenetic mechanisms of the nephrotic syndrome itself resulted in a different increase of Lp(a) in the various apo(a) isoform groups. Based on the measured Lp(a) concentrations in each subject, we calculated separately the Lp(a) concentrations arising from the two expressed isoforms by estimating the relative proportion of the two serum isoforms in the sodium dodecyl sulfate (SDS) agarose gel electrophoresis. Low-molecular-weight isoforms were associated with 40% to 75% elevated Lp(a) concentrations when compared to matched isoforms from controls. High-molecular-weight apo(a) isoforms showed 100% to 500% elevated Lp(a) levels compared to matched isoforms from controls. The severity of the nephrotic syndrome as well as the degree of renal impairment did not influence the Lp(a) concentrations. CONCLUSION: The tremendously increased Lp(a) levels in nephrotic syndrome ar caused by primary genetic as well as disease-related mechanisms.     

High lipoprotein(a) levels and small apolipoprotein(a) size prospectively predict cardiovascular events in dialysis patients

Lipoprotein(a) [Lp(a)] levels are increased in dialysis patients, suggesting that they may play a role in the elevated atherosclerotic cardiovascular disease (ASCVD) risk in this population. Few prospective studies of Lp(a) level, apolipoprotein(a) [apo(a)] size, and ASCVD have been performed in the dialysis population. An inception cohort of 833 incident dialysis patients were followed prospectively. Baseline Lp(a) was measured by apo(a) size-independent ELISA and apo(a) size by Western blot after SDS-agarose gel electrophoresis. A combined prospective nonfatal and fatal ASCVD end point included myocardial infarction, coronary revascularization, cerebrovascular accident, carotid endarterectomy, peripheral revascularization, gangrene, or limb amputation. Survival analyses were performed with adjustment for baseline demographics, comorbid conditions, ASCVD risk factors, albumin, lipids, and C-reactive protein. Median follow-up was 27.4 mo, with 297 ASCVD events, 130 non-ASCVD deaths, and seven losses to follow-up over 1649 person-years. In multivariate Cox regression models, both high Lp(a) concentration (>/=53 nmol/L) and low molecular weight (LMW) apo(a) isoforms (123 nmol/L, the relative hazard (RH) of ASCVD was 1.73 (P < 0.0005), compared with high molecular weight apo(a) and Lp(a) level <123 nmol/L. No interactions by age, race, gender, diabetes, or ASCVD were present. Both LMW apo(a) size and high Lp(a) level predict ASCVD risk in dialysis patients, but the association of ASCVD with LMW isoforms is stronger than the association with high Lp(a) concentration.     

Lipoprotein(a) and apolipoprotein(a) isoforms and proteinuria in patients with moderate renal failure.

BACKGROUND: Atherosclerotic diseases are a major cause of death in patients with renal failure. Increased serum concentrations of lipoprotein(a) [Lp(a)] have been established as a genetically controlled risk factor for these diseases and have been demonstrated in patients with moderate renal failure, suggesting that this lipoprotein contributes to the increased cardiovascular risk seen in these patients. Variable alleles at the apolipoprotein(a) [apo(a)] gene locus are the main determinants of the serum Lp(a) level in the general population. The purpose of this study was to investigate apo(a) isoforms in patients with moderate renal failure and mild proteinuria (less than 1.0 g/day). METHODS: In 250 consecutive subjects recruited at a hypertension clinic, we assessed the renal function by 24-hour creatinine clearance, proteinuria, and microalbuminuria, as well as the prevalence of atherosclerotic disease, and we also measured apo(a) isoforms, serum albumin, and Lp(a) concentrations. RESULTS: Moderate impairment of renal function (creatinine clearance, 30 to 89 ml/min per 1.73 m2 of body surface area) was found in 97 patients. Lp(a) levels were significantly greater in patients with moderate renal failure (21.7+/-23.9 mg/dl) as compared with patients with normal renal function (15.6+/-16.4 mg/dl, P<0.001), and an inverse correlation was observed between log Lp(a) and creatinine clearance (r = -0.181, P <0.01). However, no difference was found in the frequency of low molecular weight apo(a) isoforms between patients with normal (25.5%) and impaired (27.8%) renal function. Only patients with the smallest size apo(a) isoforms exhibited significantly elevated levels of Lp(a), whereas the large-size isoforms had similar concentrations in patients with normal and impaired renal function. No significant relationship was found between serum Lp(a) and proteinuria. Clinical and laboratory evidence of one or more events attributed to atherosclerosis was found in 9.8% of patients with normal renal function and 25.8% of patients with moderate renal failure (P<0.001). CONCLUSIONS: These results indicate that renal failure per se or other genes beside the apo(a) gene locus are responsible for the elevation of serum Lp(a) levels in patients with moderate impairment of renal function. The elevation of Lp(a) levels occurs independently of the level of proteinuria and may contribute to the risk for atherosclerotic disease in these patients.     

Race-specific association of lipoprotein(a) with vascular access interventions in hemodialysis patients: the CHOICE Study

BACKGROUND: Elevated serum levels of lipoprotein(a) [Lp(a)] and low molecular weight apolipoprotein(a) [apo(a)] isoforms are associated with atherothrombotic disease in the general population and in patients with kidney failure. Lp(a) may be more atherothrombotic in whites than in blacks. Data on the relation of Lp(a) and apo(a) isoform size to hemodialysis vascular access complications are limited. METHODS: We analyzed the intervention-free survival of the first arteriovenous (AV) access among 215 white and 112 black incident hemodialysis patients participating in the CHOICE Study, a national multicenter prospective cohort study. RESULTS: Median levels of Lp(a) protein were higher among blacks than whites (81.0 versus 37.5 nmol/L; P < 0.001) and inversely correlated with apo(a) isoform size (r = -0.57; P < 0.001). The incidence rate of access interventions was much higher in synthetic grafts (N = 193) than native fistulae (N = 134; 1.0 vs. 0.5 interventions per access-year; P < 0.001) and in patients with kidney failure primarily due to diabetes mellitus (N = 161) than others (N = 166; 0.9 vs. 0.6; P < 0.01), but did not differ by race. Blacks in the highest race-specific Lp(a) quartile (>145 nmol/L) had a significantly higher incidence rate than other blacks (1.4 vs. 0.7; P = 0.04), whereas no association was found in whites. The association in blacks remained after adjustment for access type and other characteristics (relative hazard = 1.68; 95% confidence interval: 0.98 to 2.86). No association was found with apo(a) isoform size in either race. CONCLUSIONS: Elevated Lp(a) may be a risk factor for arteriovenous access complications among black hemodialysis patients. Future studies should explore this possibility and be adequately powered to allow race-specific analyses.     

Pentanucleotide repeat and size polymorphisms in the apolipoprotein(a) gene are associated with the lipoprotein(a) concentration in chronic hemodialysis patients

The elevation of serum or plasma lipoprotein(a) [Lp(a)] levels is regarded as an independent risk factor for cardiovascular disease, and many previous reports demonstrated that Lp(a) levels in hemodialysis patients were significantly higher than in controls. The purpose of this study was to investigate the effect of a pentanucleotide repeat polymorphism [(TTTTA)n] in the 5'-flanking region of the apolipoprotein(a) [apo(a)] gene and of a size polymorphism of apo(a) for elevated Lp(a) concentrations observed in chronic hemodialysis patients. We studied 172 patients on chronic hemodialysis and 199 healthy adults. For analysis of the pentanucleotide repeat polymorphism, polymerase chain reaction products were loaded on polyacrylamide gel for electrophoresis. apo(a) size phenotyping was performed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and immunoblotting. The median level of Lp(a) in the patients was 14.2 mg/dl which was significantly higher than that in controls (12.0 mg/dl; p < 0.05). In the genotype of (TTTTA)8/8, the median Lp(a) level in the patients (15.9 mg/dl) was significantly higher than that in controls (13.0 mg/dl; p < 0.05). In the genotype of (TTTTA)8/8 with large-sized apo(a) isoforms (A16-A25), the patients had significantly higher Lp(a) levels than the controls (p < 0.05). In conclusion, increased Lp(a) levels in chronic hemodialysis patients were mainly attributed to the combination of eight repeats of the pentanucleotide polymorphism and large-sized isoforms of apo(a).     

Plasma and Lp(a)-associated PAF-acetylhydrolase activity in uremic patients undergoing different dialysis procedures

Plasma and Lp(a)-associated PAF-acetylhydrolase activity in uremic patients undergoing different dialysis procedures. BACKGROUND: Platelet-activating factor (PAF) is a potent inflammatory mediator associated with several physiopathological conditions, including renal diseases. PAF is degraded to the inactive metabolite lyso-PAF by PAF-acetylhydrolase (PAF-AH), which is considered as a potent anti-inflammatory and anti-atherogenic enzyme associated with lipoproteins. In this study, we evaluated the plasma- and lipoprotein(a) [Lp(a)]-associated PAF-AH activity in relationship to plasma lipid parameters and Lp(a) isoform size in patients with mild/moderate chronic renal failure (CRF), as well as in hemodialysis (HD) and chronic ambulatory peritoneal dialysis (CAPD) patients. METHODS: We studied 74 patients undergoing maintenance HD, 44 patients undergoing CAPD, 56 patients with mild/moderate CRF, and 98 healthy subjects whose lipid profile, as well as plasma and high-density lipoprotein (HDL)-associated PAF-AH activity, was determined. Moreover, the effect of Lp(a) plasma levels on the distribution of PAF-AH among plasma lipoproteins, as well as the specific activity and kinetic properties of PAF-AH on two different Lp(a) isoforms, was measured in each studied group. RESULTS: The plasma PAF-AH activity in all studied groups was significantly higher than in controls, and the increase was more profound in CAPD patients. The HDL-associated PAF-AH activity, expressed per milliliter of plasma, was similar among all studied groups; however, when it was expressed as either per milligrams of HDL cholesterol or per milligrams of plasma apolipoprotein (apo) AI, the PAF-AH activity was significantly higher in all patient groups compared with controls. All patient groups had significantly elevated plasma Lp(a) levels, which altered the distribution of PAF-AH among the plasma lipoproteins compared with that observed in subjects with very low plasma Lp(a) levels (<8 mg/dl). Additionally, in each studied group, the specific activity as well as the apparent Km and Vmax values of the 19K4 apo(a) isoform were significantly higher (P < 0.01) compared with the values of the 23K4 isoform. However, the specific activity, as well as the Km and Vmax values on either the 19K4 apo(a) isoform or the 23K4 isoform, was significantly higher in CAPD patients compared with the other three groups. CONCLUSIONS: Plasma PAF-AH activity is increased in uremic patients. This elevation is more profound in CAPD patients, who also exhibit a more atherogenic lipid profile and more pronounced alterations in the specific activity and the kinetic constants of Lp(a)-associated PAF-AH.     

Relationship of non-LDL-bound apo(a), urinary apo(a) fragments and plasma Lp(a) in patients with impaired renal function.

BACKGROUND: Plasma lipoprotein (a) [Lp(a)] has been shown to be a risk factor for atherosclerosis in numerous studies. However, the catabolism of this lipoprotein is not very clear. We and others have shown that Lp(a) is excreted into urine in the form of fragments. Lp(a) has also been shown to exist in a low-density non-lipoprotein (LDL)-bound form. Since Lp(a) is increased in all forms of kidney disease with reduced excretory kidney function and decreased excretion of apo(a) fragments could be partially responsible for this increase, we investigated the relationship of non-LDL-bound apo(a), urinary apo(a) fragments and plasma Lp(a) in patients with impaired renal function. METHODS: Plasma Lp(a), non-LDL-bound apo(a) and urinary apo(a) fragments were measured in 55 kidney disease patients (28 males and 27 females) and matched controls. RESULTS: Plasma Lp(a) and non-LDL-bound apo(a) were increased in patients, whereas urinary apo(a) was decreased, especially in patients with a creatinine clearance < 70 ml/min. There was a significant correlation between plasma Lp(a) and non-LDL-bound apo(a) in patients and controls. CONCLUSION: We conclude that decreased urinary apo(a) excretion could be one possible mechanism of increased plasma Lp(a) and non-LDL-bound apo(a) in patients with decreased kidney function.     

Plasma lipoprotein (a) levels in children with minimal lesion nephrotic syndrome

We studied the plasma lipoprotein (a)[Lp(a)] levels in 31 children with minimal lesion nephrotic syndrome (MLNS) in both stages of acute NS and remission.The mean Lp(a) levels in acute NS were significantly higher than those of the controls. The Lp(a) levels in remission were significantly lower than the Lp(a) levels in acute NS. In addition, the Lp(a) levels in remission were not significantly different from those of the controls. However, there were 5 patients whose Lp(a) levels remained higher than 30 mg/dl (the generally accepted limit for cardiovascular risk) after remission. Two of these 5 patients had Lp(a) levels greater than 40 mg/dl. In these patients apoprotein (a) [apo(a)] phenotypes were of lower molecular weight than those of the other 23 patients whose apo(a) phenotypes were examined. Additional episodes of relapse may put the patient with sustained elevated Lp(a) levels at significant risk for the development of cardiovascular disease in the long term. Received: 17 November 1998 / Revised: 9 March 1999 / Accepted: 16 March 1999     

Lipoprotein(a)- and low-density lipoprotein-derived cholesterol in nephrotic syndrome: Impact on lipid-lowering therapy?

BACKGROUND: Patients with nephrotic syndrome have the highest lipoprotein(a) [Lp(a)] concentrations known. Lp(a) is an low-density lipoprotein (LDL)-like particle consisting of 45% cholesterol. The usual methods to determine LDL cholesterol do not distinguish between cholesterol derived from LDL and Lp(a) and are thus the net result of cholesterol levels from both lipoproteins. High Lp(a) concentrations therefore significantly contribute to the measured or calculated LDL cholesterol levels. Since statins have no influence on Lp(a) levels, it can be expected that the LDL cholesterol-lowering effect of statins may be diminished in patients who have a pronounced elevation of Lp(a) levels accompanied by only moderate elevations of LDL cholesterol. METHODS: We investigated 207 patients with nondiabetic nephrotic syndrome in whom Lp(a) concentrations were strikingly elevated when compared to 274 controls (60.4 +/- 85.4 mg/dL vs. 20.0 +/- 32.8 mg/dL, P < 0.0001). RESULTS: According to National Kidney Foundation Dialysis Outcomes Quality Initiative (K/DOQI) Clinical Practice Guidelines for Managing Dyslipidemias, almost 95% of these patients are candidates for a therapeutic intervention to lower LDL cholesterol. LDL cholesterol levels corrected for Lp(a)-derived cholesterol, however, were 27 mg/dL lower than uncorrected concentrations (compared to only 9 mg/dL in controls). If Lp(a)-corrected levels instead of total LDL cholesterol levels were used, 25.7% of patients with low-molecular-weight (LMW) apolipoprotein(a) [apo(a)] isoforms were classified no longer to be in need of LDL cholesterol-lowering therapeutic intervention compared to only 2.3% of patients with high-molecular-weight (HMW) apo(a) phenotypes (P < 0.00001). This ("pseudo") pharmacogenetic effect results in incorrect determination of LDL cholesterol. CONCLUSION: Our observation has an impact on the indication for, and assessment of efficacy of intervention. This potential artifact should be investigated in ongoing large trials in renal patients as well as in nonrenal African American subjects who have on average markedly higher Lp(a) levels. In nonrenal Caucasian subjects with much lower Lp(a) concentrations, this issue will be less relevant.     

Lipoprotein(a) in the nephrotic syndrome: molecular analysis of lipoprotein(a) and apolipoprotein(a) fragments in plasma and urine

Plasma levels of lipoprotein(a) (Lp(a)), an atherogenic particle, are elevated in kidney disease, which suggests a role of this organ in the metabolism of Lp(a). Additional evidence for a role of the kidney in the clearance of Lp(a) is provided by the fact that circulating N-terminal fragments of apolipoprotein(a) (apo(a)) are processed and eliminated by the renal route. To further understand the mechanism underlying such renal excretion, the levels of apo(a) fragments in plasma and urine relative to plasma Lp(a) levels were determined in patients with nephrotic syndrome (n = 15). In plasma, the absolute (24.7 +/- 20.4 versus 2.16 +/- 2.99 microg/ml, P < 0.0001) as well as the relative amounts of apo(a) fragments (4.6 +/-3.4% versus 2.1 +/- 3.3% of total Lp(a), P < 0.0001) were significantly elevated in nephrotic patients compared with a control, normolipidemic population. In addition, urinary apo(a) excretion in patients with nephrotic syndrome was markedly elevated compared with that in control subjects (578 +/- 622 versus 27.7 +/- 44 ng/ml per mg creatinine, P < 0.001). However, the fractional catabolic rates of apo(a) fragments were similar in both groups (0.68 +/- 0.67% and 0.62 +/- 0.47% in nephrotic and control subjects, respectively), suggesting that increased plasma concentrations of apo(a) fragments in nephrotic subjects are more dependent on the rate of synthesis rather than on the catabolic rate. Molecular analysis of apo(a) immunoreactive material in urine revealed that the patterns of apo(a) fragments in nephrotic patients were distinct from those of control subjects. Full-length apo(a), large N-terminal apo(a) fragments similar in size to those present in plasma, as well as C-terminal fragments of apo(a) were detected in urine from nephrotic patients but not in urine from controls. All of these apo(a) forms were in addition to smaller N-terminal apo(a) fragments present in normal urine. This study also demonstrated the presence of Lp(a) in urine from nephrotic patients by ultracentrifugal fractionation. These data suggest that in nephrotic syndrome, Lp(a) and large fragments of apo(a) are passively filtered by the kidney through the glomerulus, whereas smaller apo(a) fragments are secreted into the urine.     

Lipoprotein (a) and the kidney

Summary: Cardiovascular disease is the main cause of death in chronic renal failure patients. Lipoprotein (a) [Lp(a)] is an independent risk factor for development of vascular disease in non-renal and renal populations. the atherogenicity of Lp(a) is thought to relate to the structural homology between its apolipoprotein moiety [apo(a)] and plasminogen. Raised low-density-lipoprotein (LDL) cholesterol concentrations increase the atherogenic potential of Lp(a). Normally Lp(a) level is genetically determined but in renal disease positive correlations with urinary protein loss and peritoneal dialysate protein loss have been found. Levels are highest in nephrotic patients and chronic renal failure patients treated with peritoneal dialysis but are also increased in pre-dialysis and haemodialysis patients. Lipoprotein (a) falls following renal transplantation but cyclosporine therapy may adversely affect post transplant cardiovascular risk profile. Treatment with antiproteinuric drugs (converting enzyme inhibitors or non-steroidal anti-inflammatory agents) has been shown to reduce Lp(a) (and total cholesterol) concentrations. Most lipid-lowering drugs do not affect Lp(a) concentration but lowering LDL-cholesterol alone may significantly reduce the atherogenic effect of Lp(a). Routine measurement of Lp(a) concentration is not recommended but antiproteinuric therapy should have favourable effects on cardiovascular risk profile.     

Lipoprotein(a) levels in relation to albumin concentration in childhood nephrotic syndrome.

BACKGROUND: Lipoprotein(a) [Lp(a)] is a lipoprotein consisting of a low-density lipoprotein (LDL) particle linked to a polymorphic glycoprotein, apoprotein(a) [apo(a)]. Prior studies have reported high Lp(a) levels in the nephrotic syndrome, but it is still controversial whether this is due to the degree of hypoalbuminemia or proteinuria. METHODS: To investigate a model of nephrotic syndrome in the absence of renal failure, we studied a group of 84 children in different clinical stages of the disease for a period of five years. We evaluated the direct relationships between lipoproteins, including Lp(a), and/or plasma albumin and proteinuria. RESULTS: Lp(a) levels were significantly higher in the subjects with the active disease compared with patients in remission, and were also significantly different when subjects were ranked by albumin quartiles. Multiple regression analysis revealed that Lp(a) levels were inversely correlated with apo(a) isoform size and plasma albumin levels but not with the proteinuria/creatinine clearance ratio. Among subjects in complete remission, Lp(a) levels were different in patients with albumin levels below or above the fifth percentile. After the improvement of the clinical stage of the disease, the Delta% variation of albumin levels was related to the Delta% of apoB and LDL cholesterol (LDL-C), but not with the Delta% variation of Lp(a), whereas the Delta% variation of LDL-C was, in turn, related to the Delta% of Lp(a) levels. CONCLUSIONS: These results suggest that in the childhood nephrotic syndrome, the increased Lp(a) levels are mainly related to hypoalbuminemia, probably through a mechanism involving apoB overproduction, which leads to an increased number of LDL particles to be converted into Lp(a).     

Urinary excretion of apo(a) in patients after kidney transplantation

Background: Increased plasma Lipoprotein (a) (Lp(a)) levels are strongly associated with premature cardiovascular disease and stroke. The kidney is purported to play an important role in apo(a) catabolism. Therefore we investigated plasma Lp(a) levels in relation to kidney function and urinary apo(a) excretion. Methods: One hundred and sixteen kidney transplant patients with normal or impaired renal function and 109 age- and sex-matched healthy controls were investigated. Plasma Lp(a) and urinary apo(a) levels were determined by routine laboratory methods. Results: Transplant recipients were found to have significantly elevated total cholesterol and LDL-C values, but equal HDL-C values compared to controls. Plasma Lp(a) values were higher and urinary apo(a) excretion was lower in transplant recipients compared to controls, independent of renal function. When the patient group was subdivided into 'normal' and 'impaired creatinine clearance', only the latter group secreted less apo(a) than normal controls. Conclusion: These data suggest that urinary apo(a) excretion is reduced in transplant recipients with impaired excretory graft function, which may contribute to the elevation of plasma Lp(a) levels in these patients.     

Factors influencing plasma lipid profiles including lipoprotein (a) concentrations in renal transplant recipients

Fasting plasma cholesterol, triglycerides, high-density lipoprotein (HDL) and apoprotein (apo) B were elevated in 214 nondiabetic renal transplant recipients renal transplant recipients when compared to a reference group. Apo (a) was slightly but not significantly lower in transplant recipients (median 118 mg/dl, range 16–1680 vs 130 mg/dl, 10–1176) and this difference could be predicted from Lp (a) isoform analysis. Cholesterol, triglyceride, apo B and apo (a) concentrations correlated negatively with creatinine clearance but none of these parameters showed a significant association with proteinuria. Patients treated with steroids had higher plasma HDL concentrations than those receiving cyclosporin monothetapy (P<0.01). The use of diuretics was associated with raised triglycerides (P<0.001) and cholesterol (P<0.01) and with reduced HDL (P<0.01) whilst patients receiving -blockers had significantly higher triglycerides (P<0.01) and lower HDL levels (P<0.02). In multiple regression analysis, age (P<0.01), creatinine clearance (P<0.05) and diuretic therapy (P<0.005) were independent risk factors for increased cholesterol whilst apo (a) levels correlated negatively with creatinine clearance (P<0.005). These results suggest that impaired renal function, steroids and non-immunosuppressive drugs contribute to lipid abnormalites in renal transplant recipients.