Genetic Variants Involved in the Crystallization Pathway Are Associated with Calcium Nephrolithiasis in the Chinese Han Population
by
Lujia Wang
1,2,†, 
Xiaoling Lin
3,†,
Zijian Zhou
1,2,†,
Yuanyuan Yang
1,2,
Peng Gao
1,2 and
Zhong Wu
1,2,* 1
Department of Urology, Huashan Hospital & Institute of Urology, Fudan University, Shanghai 200040, China
2
Clinical Research Center of Urolithiasis, Shanghai Medical College, Fudan University, Shanghai 200040, China
3
Department of Urology, Shanghai Children’s Hospital, School of Medicine, Shanghai Jiao Tong University, Shanghai 200062, China
*
Author to whom correspondence should be addressed.
†
These authors contributed equally to this work.
Genes 2022, 13(6), 943; https://doi.org/10.3390/genes13060943
Submission received: 19 March 2022
/
Revised: 12 May 2022
/
Accepted: 18 May 2022
/
Published: 25 May 2022
(This article belongs to the Special Issue Bioinformatics and Genetics of Human Diseases)
Abstract
:A genome-wide association analysis study (GWAS) in the Japanese population identified 14 significant loci associated with nephrolithiasis. Besides 4 novel loci related to metabolic traits, the 10 remaining loci were associated with kidney or electrolyte-related traits. We aimed to replicate the association of these loci with calcium nephrolithiasis in the Chinese Han population. A case–control association analysis was conducted involving 691 calcium nephrolithiasis patients and 1008 control subjects. We were able to genotype a total of 11 single-nucleotide polymorphisms (SNPs) previously identified as being correlated with nephrolithiasis in the Japanese population. SNP rs35747824 at PDILT was related to calcium nephrolithiasis in the Chinese Han population (p = 4.346 × 10−3, OR = 1.292). Moreover, four SNPs at four loci, rs6667242 at ALPL (p = 0.02999, OR = 0.8331), rs1544935 at KCNK5 (p = 0.01341, OR = 0.7804), rs7328064 at DGKH (p = 0.007452, OR = 1.211) and rs13041834 at BCAS1 (p = 0.03897, OR = 0.8409), were suggestively associated with calcium nephrolithiasis. Our results demonstrated that the genetic variants at 1p36.12, 6p21.2, 13q14.11, 16p12.3 and 20q13.2 are associated with calcium nephrolithiasis in the Chinese Han population. Furthermore, our study highlights the importance of genetic variance associated with the crystallization pathway in Chinese patients with calcium nephrolithiasis.
1. Introduction
Nephrolithiasis is a common disorder among all populations. It has been reported that the prevalence of nephrolithiasis is about 10–15% in males and 7% in females [1]. Most kidney stones are composed of calcium (70–85%), complexed to either oxalate or phosphate [2]. In urine, calcium renal calculus is formed when the relative concentrations of lithogenic substances and inhibitors of stone formation are imbalanced, which may result in crystal precipitation and aggregation [3]. It should be noted that in up to 50% of individuals, nephrolithiasis recurs within 10 years of the initial episode, and a decline in renal function has been associated with recurrent stone disease [4]. The etiology of nephrolithiasis and associated metabolic abnormalities is multifactorial, including diet, ethnicity, genetics and environmental factors [5]. Twin studies have reported heritabilities of >45% and >50% for nephrolithiasis and hypercalciuria, respectively [6,7]. Individuals with a strong family history of urolithiasis, including a parent and a sibling, have a standardized incidence ratio of >50% for developing stones [8], indicating the pivotal role of genetic factors.
Up until now, seven genome-wide association studies (GWASs) in European and Japanese populations have reported associations of nephrolithiasis with 25 loci [9,10,11,12,13,14]. In the GWAS conducted by Tanikawa et al. [14] in the Japanese population, they identified 14 significant loci, including 9 novel loci. Four novel loci were related to metabolic traits, whereas the remaining 10 loci were associated with kidney or electrolyte-related traits which may impact the crystallization pathways of urolithiasis. In this study, we conducted a replication study regarding the association between polymorphisms at these loci and the risk of calcium nephrolithiasis in the Chinese Han population. We believe that our results may help to elucidate the molecular pathology of calcium nephrolithiasis in Chinese patients.
2. Material and Methods
2.1. Ethics Statement
The protocol for this study was compliant with the Declaration of Helsinki. All participants gave their written informed consent before participating in this study. Approval of the research protocol was obtained from the Huashan Institutional Review Board of Fudan University (HIRB).
2.2. Subjects
In total, 691 unrelated Chinese Han patients with nephrolithiasis (467 males and 224 females, mean age: 50.47 years) were recruited at Huashan Hospital of Fudan University. The procedure eliminated patients with radioparent stones, such as cystine, struvite and uric acid stones. Moreover, secondary nephrolithiasis in patients with known causes, including gout, renal failure, hyperparathyroidism, osteoporosis or cancer were excluded. Also excluded were those taking calcium and/or vitamin D supplements or taking medications that may affect urinary calcium excretion. In the control group, there were 1,008 subjects without a family history of nephrolithiasis or stone disease. Calcium nephrolithiasis was diagnosed clinically either with plain kidney–ureter–bladder (KUB) radiography or a non-contrast computed tomography (NCCT) scan. All the patients with calcium nephrolithiasis and the control subjects belonged to the same racial, ethnic, geographical and environmental strata.
We assessed the effect of genetic variations on serum sodium, potassium, calcium, magnesium, phosphorus, chloride, carbon dioxide (CO2), creatinine, urea, uric acid, alkaline phosphatase (ALP), parathyroid hormone (PTH), albumin, glucose, 25(OH)D3, cholesterol, triglyceride, low-density lipoprotein (LDL), high-density lipoprotein (HDL), urine calcium and phosphorus levels, as well as estimated glomerular filtration rate (eGFR) and body mass index (BMI).
2.3. SNP Selection and Genotyping
A standard quality control procedure was applied to select SNPs for further analysis. SNPs with the following conditions were excluded: (i) genotype call rate < 90%; (ii) minor allele frequency (MAF) < 0.01; or (iii) p < 0.001 for the Hardy–Weinberg equilibrium (HWE) test. We were able to genotype a total of 17 single-nucleotide polymorphisms (SNPs) significantly associated with nephrolithiasis in GWAS.
2.4. Statistical Analysis
Quantitative data were expressed as mean ± standard deviation (SD). Continuous variables were tested with an independent t-test. The chi-square test was used to analyze categorical variables. Genotype distributions for the SNPs were tested for Hardy–Weinberg equilibrium (HWE). SNP associations with nephrolithiasis were examined by a Cochran–Armitage trend test. Results are expressed as odds ratios (ORs) and 95% confidence intervals (CI). A p-value lower than 4.545 × 10−3 (0.05/11) was considered statistically significant. SNPs with a p-value less than 0.05 were also considered of interest. Multiple logistic regression analyses were conducted to investigate the relationship between genotype and recurrent disease, hypertension and diabetes mellitus. Genotype and clinical parameters were tested through multiple linear regression analyses. We conducted association and QTL analyses using the PLINK-1.07 toolset. p-values were two-tailed. An α of 0.05 indicated statistical significance.
3. Results
Table 1 showed the clinical characteristics of the case and control samples. Compared with the healthy controls, body mass index (BMI) was significantly higher in patients with calcium nephrolithiasis (p = 0.003). No significant difference was observed in the distribution of serum calcium, phosphorus, magnesium, creatinine, uric acid, albumin, triglycerides and cholesterol between the patients and controls.
Table 2 shows the genotype frequencies of polymorphism among all subjects. The genotype frequencies of 11 SNPs were distributed in accordance with the Hardy–Weinberg equilibrium. The SNP rs35747824 at PDILT had a significant association with calcium nephrolithiasis in the Chinese Han population (p = 4.346 × 10−3, OR = 1.292). Moreover, four SNPs at four loci, rs6667242 at ALPL (p = 0.02999, OR = 0.8331), rs1544935 at KCNK5 (p = 0.01341, OR = 0.7804), rs7328064 at DGKH (p = 0.007452, OR = 1.211) and rs13041834 at BCAS1 (p = 0.03897, OR = 0.8409), were suggestively associated with the risk of calcium nephrolithiasis. The A allele of rs6667242, the T allele of rs1544935, the C allele of rs7328064, the T rs35747824 and the T allele of rs13041834 were found to increase the risk of nephrolithiasis development.
Next, we examined the association of these significant SNPs with several clinical parameters. As shown in Table 3, there were no significant SNPs related to recurrent nephrolithiasis disease, hypertension or diabetes mellitus. As shown in Table 4, the T allele of rs35747824 was significantly correlated with higher levels of serum urea (p = 0.01471) and urine phosphorus (p = 0.01966). The T allele of rs1544935 was significantly correlated with a lower level of urine calcium (p = 0.03293). The T allele of rs13041834 was significantly correlated with a higher level of serum magnesium (p = 0.008117).
4. Discussion
In 2019, Tanikawa et al. [14] conducted a GWAS for urolithiasis in the Japanese population which included more than 13,000 cases and 190,000 control samples. They found 14 significant loci, including 9 novel loci, that were associated with the risk of urolithiasis in the Japanese population. Four novel loci (2p23.3, 6p12.3, 16q12.2 and 17q23.2) could potentially promote the formation of urolithiasis through the regulation of metabolic traits, such as obesity and increased levels of uric acid. Four previously reported loci (5q35.3, 7q14.3 13q14.11 and 21q22.13) and three of the novel loci (6q23.2, 20q13.2 and 19q13.12) were associated with the regulation of serum and urine calcium levels. The other three loci (1p36.12, 6p21.2 and 16p12.3) were speculated to regulate the crystallization step of calcium nephrolithiasis. Thus, all 14 loci were speculated to be associated with the regulation of either the metabolic or crystallization pathways of lithogenesis. In this study, we evaluated the association of 11 single-nucleotide polymorphisms (SNPs) at 11 loci identified in former GWASs as being related to nephrolithiasis in the Chinese Han population. We demonstrated that rs6667242 at 1p36.12, rs1544935 at 6p21.2, rs7328064 at 13q14.11, rs35747824 at 16p12.3 and rs13041834 at 20q13.2 were associated with risk of calcium nephrolithiasis in Chinese patients.
rs35747824 is located in the intron of PDILT, within the UMOD-PDILT locus at 16p12.3. UMOD encodes uromodulin, the most abundant protein in urine and a known inhibitor of calcium–phosphate precipitation. Studies have shown that UMOD knockout mice had lower creatinine clearance and were more susceptible to urinary tract infections [15,16]. In a meta-analysis study of common variants in UMOD, the adjacent gene PDILT (protein disulfide isomerase-like, testis expressed) was significantly associated with urinary uromodulin levels [17]. Another meta-analysis indicated that SNPs within PDILT-UMOD were associated with rapid kidney function decline [18]. Furthermore, a common variant at UMOD has been identified as a protective SNP against nephrolithiasis in a GWAS [10]. In the GWAS by Tanikawa et al. [14], rs35747824 was significantly associated with urolithiasis in the Japanese population. The authors suggested that rs35747824 was associated with kidney-related traits, since the allele of rs35747824 was correlated with higher serum urea, creatinine and uric acid and lower eGFR. In our study, rs35747824 was significantly associated with risk of calcium nephrolithiasis in the Chinese Han population. The risk allele rs35747824 was correlated with higher levels of serum urea and urine phosphorus, which suggested that the PDILT-UMOD locus was not only associated with kidney-related traits but also with electrolyte-related traits. It has been proven that high urine phosphate is an important risk factor for calcium nephrolithiasis. It was reported that increased phosphaturia could upregulate 1-α hydroxylase activity and that it increased 1,25 vitamin D, which ultimately led to hypercalciuria and calcium nephrolithiasis [19].
rs1544935 at 6p21.2 is located within KCNK5, which encodes potassium two pore domain channel subfamily K member 5 (KCNK5). KCNK5 is strongly expressed in renal proximal tubules and papillary collecting ducts. KCNK5 knockout mice exhibit metabolic acidosis due to renal loss of carbonate [20]. In the kidneys, KCNK5 plays an important role in maintaining normal levels of plasma potassium, as well as exerting various functions, including cell volume control, membrane potential stabilization and excitability, and regulation of hormone or ion secretion [21]. However, the role of the KCNK5 gene polymorphism in calcium nephrolithiasis has not been fully elucidated. In a GWAS in British and Japanese populations by Howles et al. [13], rs1155347 at KCNK5 was associated with nephrolithiasis in a trans-ethnic meta-analysis. In a GWAS in the Japanese population, rs1544935 at KCNK5 was identified as being related to risk of urolithiasis [14] and the authors presumed that this variant might promote stone formation by regulating urine pH levels. In the present study, rs1544935 showed a suggestive significant association with calcium nephrolithiasis in the Chinese Han population.
rs13041834 at 20q13.2 is located near CYP24A1, which encodes cytochrome P450 family 24 subfamily A member 1 (CYP24A1), an enzyme that metabolizes active 1,25-dihydroxyvitamin D into inactive 24,25-dihydroxyvitamin D. It was reported that loss-of-function mutations in CYP24A1 caused autosomal recessive infantile hypercalcemia type 1 (OMIM 126065) [22]. In the GWAS by Howles et al. [13], a genome-wide significant SNP associated with nephrolithiasis, rs17216707, was identified in British and Japanese populations; the allele is ~38 kb upstream of CYP24A1. Individuals homozygous for the CYP24A1 risk allele rs17216707-T had significantly higher serum calcium concentrations than heterozygotes [13]. In the GWAS by Tanikawa et al. [14], among the Japanese population, rs13041834 obviously increased the risk of urinary calculi. In our study, rs13041834 showed a suggestive association with calcium nephrolithiasis in the Chinese Han population, and the risk allele rs13041834 was correlated with higher levels of serum magnesium. Since magnesium is well maintained in the body by the kidneys, we speculated that higher serum magnesium levels could be attributed to the impaired urine concentration affected by rs13041834. As an inhibitor of kidney stones, magnesium competes with calcium to bind oxalates in urine and the ratio of magnesium/calcium in urine is correlated with risk of nephrolithiasis [23].
ALPL encodes the alkaline phosphatase tissue-nonspecific isozyme (ALPL), which is expressed in the proximal tubules of the kidney [24]. In the GWAS by Oddsson et al. [12] in Icelanders, they identified protective and risk genes for nephrolithiasis that were correlated with elevated and reduced serum ALP levels, respectively. As alkaline phosphatase (ALP) hydrolyzes pyrophosphate into free phosphate, the risk of nephrolithiasis associated with the variants of ALPL should be dependent on the balance between stone-inhibiting pyrophosphate and phosphate in the kidneys [25]. Li et al. [26] replicated the GWAS in Icelanders and identified rs1256328 at ALPL as being associated with nephrolithiasis in the Chinese Han population. In the GWAS by Tanikawa et al. [14], rs6667242 at 1p36.12 showed a significant association with urolithiasis in the Japanese population. The risk allele rs6667242 was associated with higher serum ALP levels and lower serum phosphate levels. Although we observed the association of rs6667242 with calcium nephrolithiasis in the Chinese Han population in the present study, the risk allele rs6667242 was not correlated with any of the electrolyte traits.
DGKH encodes for diacylglycerol kinase eta (DGKH). In the GWAS by Urabe et al., they first identified DGKH at 13q14.11 as being associated with calcium nephrolithiasis in the Japanese population [11]. However, we failed to replicate the finding of an association of rs7981733, rs4142110 and rs17646069 with DGKH in the Chinese Han population in our previous study [27]. In the GWAS of Howles et al. [13], an intronic variant in DGKH, rs1037271, was associated with nephrolithiasis in British and Japanese populations, and the authors suggested that SNPs of DGKH were predicted to promote kidney stone formation by influencing CaSR signaling. In the GWAS by Tanikawa et al. [14], it was reported that rs7328064 in DGKH was significantly associated with urolithiasis in the Japanese population. The risk allele rs7328064 was correlated with lower levels of serum creatinine and higher eGFRs, which demonstrated that rs7328064 might also be associated with kidney-related traits. In our results, rs7328064 showed a suggestive association with calcium nephrolithiasis in the Chinese Han population.
In the present study, we were able to replicate 11 SNPs discovered in the GWAS of nephrolithiasis by Tanikawa et al. [14]. To our knowledge, there are no similar studies replicating the results of their GWAS in the Chinese Han population. It is worth noting that most of the significant SNPs validated in our study were involved in calcium metabolism or crystallization in the kidneys, rather than the metabolic pathway (Figure 1). This discrepancy can be partly explained by the fact that stone composition in our study was limited to calcium-containing stones. Remarkably, our results indicated the important role of genetic variance associated with calcium metabolism and the crystallization pathway in calcium nephrolithiasis.
5. Conclusions
To conclude, our results demonstrated that genetic variants at 1p36.12, 6p21.2, 13q14.11, 16p12.3 and 20q13.2 are associated with calcium nephrolithiasis in the Chinese Han population. Since the variants at 13q14.11 and 20q13.2 are related to calcium metabolism in the kidneys and the variants at 1p36.12, 6p21.2 and 16p12.3 are speculated to regulate the crystallization step of lithogenesis, our results highlight the importance of genetic variance associated with the crystallization pathway in Chinese patients with calcium nephrolithiasis.
Author Contributions
Conceptualization, Z.W. and L.W.; methodology, Z.Z.; software, Y.Y.; formal analysis, P.G.; investigation, Z.Z. and X.L.; writing—original draft preparation, L.W.; writing—review and editing, Z.W. and P.G.; supervision, X.L. All authors have read and agreed to the published version of the manuscript.
Funding
This work was supported by the National Natural Science Foundation of China (grant numbers: 81970603 and 82100807) and the Scientific Research Foundation of Huashan Hospital Northern Branch (grant number: HSBY2019003).
Institutional Review Board Statement
The research protocol was approved by the Huashan Institutional Review Board of Fudan University (HIRB) (Protocol code: 2020-724).
Informed Consent Statement
Informed consent was obtained from all subjects involved in the study.
Data Availability Statement
Data could be made available upon reasonable request to the authors.
Conflicts of Interest
The authors declare no conflict of interest.
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Figure 1.
Schematic of the related components of the kidney calcium metabolism and crystallization pathways considered in the present study, including the putative effector genes and corresponding SNPs. The newly discovered correlations are shown in red.
Figure 1.
Schematic of the related components of the kidney calcium metabolism and crystallization pathways considered in the present study, including the putative effector genes and corresponding SNPs. The newly discovered correlations are shown in red.
Table 1.
Baseline characteristics of the study population. The bold means statistically significant difference.
Table 1.
Baseline characteristics of the study population. The bold means statistically significant difference.
| Parameters | Cases (n = 691) | Controls (n = 1008) | p-Value |
|---|---|---|---|
| Gender (male/female) | 467/224 | 705/303 | 0.302 |
| Age (years) | 50.47 ± 12.55 | 49.98 ± 12.65 | 0.431 |
| BMI (kg/m2) | 24.76 ± 3.30 | 24.28 ± 3.26 | 0.003 |
| Stone frequency (primary/recurrence) | 418/273 | - | - |
| Serum calcium (mmol/L) | 2.26 ± 0.12 | 2.27 ± 0.10 | 0.062 |
| Serum phosphorus (mmol/L) | 1.13 ± 0.21 | 1.14 ± 0.18 | 0.293 |
| Serum magnesium (mmol/L) | 0.91 ± 0.93 | 0.89 ± 0.75 | 0.625 |
| Serum creatinine (μmol/L) | 85.19 ± 41.93 | 83.64 ± 23.51 | 0.331 |
| Serum uric acid (mmol/L) | 0.360 ± 0.088 | 0.353 ± 0.077 | 0.083 |
| Serum albumin (g/L) | 42.11 ± 4.11 | 41.86 ± 4.09 | 0.217 |
| Serum triglycerides (mmol/L) | 1.59 ± 0.80 | 1.62 ± 0.84 | 0.461 |
| Serum cholesterol (mmol/L) | 4.60 ± 1.24 | 4.65 ± 1.22 | 0.410 |
Table 2.
Results of the association analysis for calcium nephrolithiasis in the Chinese Han population.
Table 2.
Results of the association analysis for calcium nephrolithiasis in the Chinese Han population.
| Chr. | SNP | Region | Gene | Alleles | Cases | Controls | p | OR | 95%CI | |||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| Minor | Major | n(11) a | n(12) | n(22) | MAF | n(11) | n(12) | n(22) | MAF | |||||||
| 1 | rs6667242 | 1p36.12 | ALPL | G | A | 34 | 219 | 297 | 0.2609 | 83 | 434 | 491 | 0.2976 | 0.02999 | 0.8331 | 0.7064–0.9826 |
| 2 | rs1260326 | 2p23.3 | GCKR | C | T | 142 | 328 | 221 | 0.4428 | 207 | 507 | 293 | 0.4573 | 0.4054 | 0.9432 | 0.8219–1.082 |
| 5 | rs11746443 | 5q35.3 | RGS14 | A | G | 21 | 222 | 448 | 0.191 | 39 | 271 | 698 | 0.1731 | 0.1822 | 1.128 | 0.945–1.346 |
| 6 | rs1544935 | 6p21.2 | KCNK5 | G | T | 12 | 154 | 498 | 0.134 | 26 | 281 | 699 | 0.1655 | 0.01341 | 0.7804 | 0.641–0.9502 |
| 6 | rs3798519 | 6p12.3 | TFAP2B | C | A | 48 | 244 | 371 | 0.2564 | 46 | 358 | 566 | 0.232 | 0.109 | 1.142 | 0.9708–1.343 |
| 6 | rs6928986 | 6q23.2 | EPB41L2 | C | T | 109 | 296 | 238 | 0.3997 | 152 | 483 | 354 | 0.3979 | 0.9177 | 1.008 | 0.873–1.163 |
| 7 | rs6975977 | 7p14.3 | INMT-FAM188B | A | G | 7 | 105 | 553 | 0.08947 | 15 | 180 | 797 | 0.1058 | 0.1223 | 0.8301 | 0.6553–1.052 |
| 13 | rs7328064 | 13q14.11 | DGKH | C | A | 171 | 347 | 160 | 0.5081 | 179 | 487 | 252 | 0.4602 | 0.007452 | 1.211 | 1.053–1.394 |
| 16 | rs35747824 | 16p12.3 | PDILT | T | A | 32 | 222 | 430 | 0.2091 | 37 | 252 | 671 | 0.1698 | 0.004346 * | 1.292 | 1.083–1.542 |
| 19 | rs74956940 | 19p13.12 | PKN1 | G | C | 25 | 183 | 395 | 0.1932 | 32 | 298 | 624 | 0.1897 | 0.8102 | 1.023 | 0.8516–1.228 |
| 20 | rs13041834 | 20q13.2 | BCAS1 | C | T | 26 | 241 | 415 | 0.2148 | 62 | 365 | 569 | 0.2455 | 0.03897 | 0.8409 | 0.7132–0.9914 |
Abbreviations: Chr., chromosome; CI, confident interval; MAF, minor allele frequency; OR, odds ratio; SNP, single-nucleotide polymorphism. a n(11), number of subjects with homozygous genotypes for the minor allele; n(12), number of subjects with heterozygous genotypes; n(22), number of subjects with homozygous genotypes for the major allele. * p < 0.05/11
Table 3.
Multiple logistic regression analyses for clinical parameters.
| SNP | Recurrent Disease | Hypertension | Diabetes Mellitus | ||||||
|---|---|---|---|---|---|---|---|---|---|
| OR | s.e. b | p | OR | s.e. | p | OR | s.e. | p | |
| rs6667242 | 0.8 | 0.2441 | 0.3601 | 1.227 | 0.2345 | 0.3824 | 1.075 | 0.3571 | 0.8405 |
| rs1544935 | 1.411 | 0.2953 | 0.2417 | 0.8592 | 0.3074 | 0.6211 | 1.352 | 0.4152 | 0.4664 |
| rs7328064 | 0.9796 | 0.1994 | 0.9177 | 0.7451 | 0.1992 | 0.1393 | 1.176 | 0.3007 | 0.5894 |
| rs35747824 | 1.072 | 0.2453 | 0.7766 | 0.9031 | 0.2476 | 0.6807 | 0.7811 | 0.3871 | 0.5224 |
| rs13041834 | 0.7783 | 0.2465 | 0.3084 | 1.113 | 0.2373 | 0.6518 | 0.9484 | 0.3609 | 0.8832 |
Abbreviations: SNP, single-nucleotide polymorphism; OR, odds ratio. b s.e., standard error of mean.
Table 4.
Multiple linear regression analyses for clinical parameters.
| rs6667242 | rs1544935 | rs7328064 | rs35747824 | rs13041834 | |||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| Beta c | s.e. d | p | Beta | s.e. | p | Beta | s.e. | p | Beta | s.e. | p | Beta | s.e. | p | |
| eGFR e | 1.594 | 3.844 | 0.6796 | 2.419 | 5.014 | 0.6308 | −1.834 | 3.381 | 0.5891 | 2.161 | 3.823 | 0.5734 | −0.654 | 3.587 | 0.8558 |
| Serum creatinine | 1.661 | 4.136 | 0.6884 | −4.099 | 5.342 | 0.4438 | 4.984 | 3.665 | 0.1753 | −0.9605 | 4.39 | 0.827 | −4.37 | 4.222 | 0.3018 |
| Serum urea | −0.3615 | 0.5457 | 0.5085 | −0.02013 | 0.3084 | 0.948 | −0.2489 | 0.4711 | 0.5978 | 1.365 | 0.5549 | 0.01471 | −0.765 | 0.5394 | 0.1575 |
| Serum uric acid | 0.006173 | 0.01069 | 0.5643 | −0.01249 | 0.01372 | 0.3636 | 0.006789 | 0.009428 | 0.4723 | 0.02088 | 0.0112 | 0.06371 | 0.01506 | 0.01083 | 0.1656 |
| Serum sodium | 0.1369 | 0.2913 | 0.6389 | −0.1459 | 0.3693 | 0.6933 | −0.3738 | 0.252 | 0.1394 | 0.1134 | 0.3035 | 0.709 | −0.06286 | 0.2926 | 0.8301 |
| Serum potassium | 0.2138 | 0.3062 | 0.4858 | −0.1813 | 0.3805 | 0.6342 | 0.43 | 0.2603 | 0.09995 | −0.2452 | 0.312 | 0.4327 | 0.234 | 0.3006 | 0.4371 |
| Serum calcium | −0.00702 | 0.01335 | 0.5996 | −0.01898 | 0.01705 | 0.2667 | 0.01394 | 0.01172 | 0.2355 | 0.01066 | 0.01401 | 0.4473 | −0.009201 | 0.0135 | 0.4964 |
| Serum magnesium | −0.17 | 0.1978 | 0.3912 | 0.3997 | 0.2447 | 0.1039 | 0.007906 | 0.1692 | 0.9628 | −0.1604 | 0.2013 | 0.4267 | 0.51 | 0.1908 | 0.008117 |
| Serum phosphorus | −0.02663 | 0.0203 | 0.1912 | 0.02217 | 0.02614 | 0.3974 | −0.004899 | 0.018 | 0.7858 | 0.01873 | 0.02136 | 0.3816 | 0.02346 | 0.02064 | 0.2571 |
| Serum chloride | 1.586 | 1.351 | 0.2431 | 1.102 | 1.826 | 0.5474 | 0.3793 | 1.205 | 0.7535 | 0.4335 | 1.586 | 0.7851 | 1.012 | 1.515 | 0.5055 |
| Serum CO2 | −0.4642 | 0.3749 | 0.2171 | 0.6859 | 0.4757 | 0.1507 | −0.08025 | 0.3284 | 0.8072 | 0.1175 | 0.3898 | 0.7633 | 0.7341 | 0.3747 | 0.05135 |
| Serum ALP | −3.448 | 3.492 | 0.3247 | −7.364 | 4.454 | 0.0997 | 4.283 | 3.069 | 0.1643 | −1.573 | 3.678 | 0.6693 | −6.496 | 3.517 | 0.06609 |
| PTH | 10.5 | 15.4 | 0.5015 | −3.914 | 21.34 | 0.8558 | −6.033 | 14.16 | 0.6733 | 0.01759 | 15.14 | 0.9991 | −15.24 | 15.92 | 0.3467 |
| Serum 25(OH)D3 | −0.8105 | 5.833 | 0.8906 | 9.349 | 8.259 | 0.2676 | −0.7929 | 4.926 | 0.8733 | −3.922 | 6.088 | 0.5249 | 5.433 | 6.045 | 0.3767 |
| BMI | −0.4291 | 0.3849 | 0.2662 | −0.4376 | 0.5037 | 0.386 | −0.2049 | 0.3431 | 0.5511 | 0.1449 | 0.4138 | 0.7266 | −0.2607 | 0.3986 | 0.5137 |
| Serum albumin | −0.2966 | 0.4241 | 0.4852 | −0.2503 | 0.546 | 0.6471 | 0.1871 | 0.377 | 0.6203 | 0.2914 | 0.4495 | 0.5175 | −0.06749 | 0.4336 | 0.8765 |
| Serum glucose | −0.2328 | 0.1266 | 0.06755 | 0.08015 | 0.2012 | 0.6908 | −0.0169 | 0.1355 | 0.9009 | −0.1584 | 0.16 | 0.3232 | −0.05665 | 0.1545 | 0.7142 |
| Serum total cholesterol | −0.364 | 0.783 | 0.6492 | 1.083 | 0.6451 | 0.1139 | 0.4715 | 0.6727 | 0.4942 | −0.9325 | 0.8684 | 0.3011 | −1.063 | 0.8388 | 0.2242 |
| Serum triglycerides | 0.014 | 0.2162 | 0.9493 | 0.1763 | 0.1836 | 0.3521 | −0.04755 | 0.1835 | 0.7991 | −0.2038 | 0.2344 | 0.3992 | −0.04 | 0.2372 | 0.8684 |
| Serum LDL | −0.5435 | 0.6112 | 0.3889 | 0.6954 | 0.5457 | 0.2219 | 0.2475 | 0.5549 | 0.6619 | −0.8462 | 0.7018 | 0.2479 | −0.9212 | 0.6807 | 0.196 |
| Serum HDL | 0.1274 | 0.09721 | 0.2126 | 0.07761 | 0.09409 | 0.4233 | 0.07893 | 0.08858 | 0.388 | 0.02964 | 0.1238 | 0.8145 | −0.04367 | 0.1187 | 0.7185 |
| Urine calcium | 0.15 | 0.9464 | 0.8765 | −3.358 | 1.419 | 0.03293 | 0.3711 | 0.9964 | 0.7151 | −0.9279 | 1.216 | 0.4591 | −0.8074 | 1.174 | 0.5029 |
| Urine phosphorus | 0.6714 | 4.999 | 0.8952 | −11.72 | 5.798 | 0.06287 | 4.387 | 3.75 | 0.2617 | 10.46 | 3.934 | 0.01966 | 1.947 | 4.655 | 0.6821 |
| Urine pH | −0.04856 | 0.08224 | 0.5555 | 0.005251 | 0.1041 | 0.9598 | −0.0004832 | 0.07171 | 0.9946 | −0.005472 | 0.08558 | 0.9491 | −0.02474 | 0.08241 | 0.7643 |
Abbreviations: eGFR, estimated glomerular filtration rate; ALP, alkaline phosphatase; PTH, parathyroid hormone; 25(OH)D3, 25-hydroxycholecalciferol; BMI, body mass index; LDL, low-density lipoprotein; HDL, high-density lipoprotein. c Beta, Regression coefficient. d s.e., standard error of mean. e eGFR (mL/min/1.73 m2) = 186 × (serum creatinine/88.41)−1.154 × age−0.203 (×0.742 if female). The bold p means statistically significant difference.
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Wang, L.; Lin, X.; Zhou, Z.; Yang, Y.; Gao, P.; Wu, Z. Genetic Variants Involved in the Crystallization Pathway Are Associated with Calcium Nephrolithiasis in the Chinese Han Population. Genes 2022, 13, 943. https://doi.org/10.3390/genes13060943
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Wang L, Lin X, Zhou Z, Yang Y, Gao P, Wu Z. Genetic Variants Involved in the Crystallization Pathway Are Associated with Calcium Nephrolithiasis in the Chinese Han Population. Genes. 2022; 13(6):943. https://doi.org/10.3390/genes13060943
Chicago/Turabian StyleWang, Lujia, Xiaoling Lin, Zijian Zhou, Yuanyuan Yang, Peng Gao, and Zhong Wu. 2022. "Genetic Variants Involved in the Crystallization Pathway Are Associated with Calcium Nephrolithiasis in the Chinese Han Population" Genes 13, no. 6: 943. https://doi.org/10.3390/genes13060943
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