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Query: UMLS:C0020500 (
hyperoxaluria
)
912
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Anion transporters NaS1 (SLC13A1) and Sat1 (
SLC26A1
) mediate sulfate (re)absorption across renal proximal tubule and small intestinal epithelia, thereby regulating blood sulfate levels. Disruption of murine NaS1 and Sat1 genes leads to hyposulfatemia and hypersulfaturia. Sat1-null mice also exhibit hyperoxalemia,
hyperoxaluria
, and calcium oxalate urolithiasis. This review will highlight the current pathophysiological features of NaS1- and Sat1-null mice resulting from alterations in circulating sulfate and oxalate anion levels.
...
PMID:Slc13a1 and Slc26a1 KO models reveal physiological roles of anion transporters. 2288 9
Mice deficient for the apical membrane oxalate transporter SLC26A6 develop hyperoxalemia,
hyperoxaluria
, and calcium oxalate stones due to a defect in intestinal oxalate secretion. However, the nature of the basolateral membrane oxalate transport process that operates in series with SLC26A6 to mediate active oxalate secretion in the intestine remains unknown. Sulfate anion transporter-1 (Sat1 or
SLC26A1
) is a basolateral membrane anion exchanger that mediates intestinal oxalate transport. Moreover, Sat1-deficient mice also have a phenotype of hyperoxalemia,
hyperoxaluria
, and calcium oxalate stones. We, therefore, tested the role of Sat1 in mouse duodenum, a tissue with Sat1 expression and SLC26A6-dependent oxalate secretion. Although the active secretory flux of oxalate across mouse duodenum was strongly inhibited (>90%) by addition of the disulfonic stilbene DIDS to the basolateral solution, secretion was unaffected by changes in medium concentrations of sulfate and bicarbonate, key substrates for Sat1-mediated anion exchange. Inhibition of intracellular bicarbonate production by acetazolamide and complete removal of bicarbonate from the buffer also produced no change in oxalate secretion. Finally, active oxalate secretion was not reduced in Sat1-null mice. We conclude that a DIDS-sensitive basolateral transporter is involved in mediating oxalate secretion across mouse duodenum, but Sat1 itself is dispensable for this process.
...
PMID:Sat1 is dispensable for active oxalate secretion in mouse duodenum. 2251 57
Kidney stones are a global health problem, incurring massive health costs annually. Why stones recur in many patients remains unknown but likely involves environmental, physiological, and genetic factors. The solute linked carrier (SLC) 26A1 gene has previously been linked to kidney stones in mice.
SLC26A1
encodes the sulfate anion transporter 1 (SAT1) protein, and its loss in mice leads to
hyperoxaluria
and calcium oxalate renal stones. To investigate the possible involvement of SAT1 in human urolithiasis, we screened the
SLC26A1
gene in a cohort of 13 individuals with recurrent calcium oxalate urolithiasis, which is the commonest type. DNA sequence analyses showed missense mutations in seven patients: one individual was heterozygous R372H; 4 individuals were heterozygous Q556R; one patient was homozygous Q556R; and one patient with severe nephrocalcinosis (requiring nephrectomy) was homozygous Q556R and heterozygous M132T. The M132 amino acid in human SAT1 is conserved with 15 other species and is located within the third transmembrane domain of the predicted SAT1 protein structure, suggesting that this amino acid may be important for SAT1 function. These initial findings demonstrate genetic variants in
SLC26A1
of recurrent stone formers and warrant wider independent studies of
SLC26A1
in humans with recurrent calcium oxalate stones.
...
PMID:Human SLC26A1 gene variants: a pilot study. 2425 Feb 68
Oxalate urolithiasis (nephrolithiasis) is the most frequent type of kidney stone disease. Epidemiological research has shown that urolithiasis is approximately twice as common in men as in women, but the underlying mechanism of this sex-related prevalence is unclear. Oxalate in the organism partially originate from food (exogenous oxalate) and largely as a metabolic end-product from numerous precursors generated mainly in the liver (endogenous oxalate). Oxalate concentrations in plasma and urine can be modified by various foodstuffs, which can interact in positively or negatively by affecting oxalate absorption, excretion, and/or its metabolic pathways. Oxalate is mostly removed from blood by kidneys and partially via bile and intestinal excretion. In the kidneys, after reaching certain conditions, such as high tubular concentration and damaged integrity of the tubule epithelium, oxalate can precipitate and initiate the formation of stones. Recent studies have indicated the importance of the SoLute Carrier 26 (SLC26) family of membrane transporters for handling oxalate. Two members of this family [Sulfate Anion Transporter 1 (
SAT-1
;
SLC26A1
) and Chloride/Formate EXchanger (CFEX; SLC26A6)] may contribute to oxalate transport in the intestine, liver, and kidneys. Malfunction or absence of
SAT-1
or CFEX has been associated with
hyperoxaluria
and urolithiasis. However, numerous questions regarding their roles in oxalate transport in the respective organs and male-prevalent urolithiasis, as well as the role of sex hormones in the expression of these transporters at the level of mRNA and protein, still remain to be answered.
...
PMID:Oxalate: from the environment to kidney stones. 2438 68
Genetic deficiency of the
SLC26A1
anion exchanger in mice is known to be associated with hyposulfatemia and
hyperoxaluria
with nephrolithiasis, but many aspects of human
SLC26A1
function remain to be explored. We report here the functional characterization of human
SLC26A1
, a 4,4'-diisothiocyanato-2,2'-stilbenedisulfonic acid (DIDS)-sensitive, electroneutral sodium-independent anion exchanger transporting sulfate, oxalate, bicarbonate, thiosulfate, and (with divergent properties) chloride. Human
SLC26A1
-mediated anion exchange differs from that of its rodent orthologs in its stimulation by alkaline pHo and inhibition by acidic pHo but not pHi and in its failure to transport glyoxylate.
SLC26A1
-mediated transport of sulfate and oxalate is highly dependent on allosteric activation by extracellular chloride or non-substrate anions. Extracellular chloride stimulates apparent V max of human
SLC26A1
-mediated sulfate uptake by conferring a 2-log decrease in sensitivity to inhibition by extracellular protons, without changing transporter affinity for extracellular sulfate. In contrast to
SLC26A1
-mediated sulfate transport,
SLC26A1
-associated chloride transport is activated by acid pHo, shows reduced sensitivity to DIDS, and exhibits cation dependence of its DIDS-insensitive component. Human
SLC26A1
resembles SLC26 paralogs in its inhibition by phorbol ester activation of protein kinase C (PKC), which differs in its undiminished polypeptide abundance at or near the oocyte surface. Mutation of
SLC26A1
residues corresponding to candidate anion binding site-associated residues in avian SLC26A5/prestin altered anion transport in patterns resembling those of prestin. However, rare
SLC26A1
polymorphic variants from a patient with renal Fanconi Syndrome and from a patient with nephrolithiasis/calcinosis exhibited no loss-of-function phenotypes consistent with disease pathogenesis.
...
PMID:Extracellular Cl(-) regulates human SO4 (2-)/anion exchanger SLC26A1 by altering pH sensitivity of anion transport. 2712 15
The anion exchanger
SAT-1
[sulfate anion transporter 1 (Slc26a1)] is considered an important regulator of oxalate and sulfate homeostasis, but the mechanistic basis of these critical roles remain undetermined. Previously, characterization of the
SAT-1
-knockout (KO) mouse suggested that the loss of
SAT-1
-mediated oxalate secretion by the intestine was responsible for the
hyperoxaluria
, hyperoxalemia, and calcium oxalate urolithiasis reportedly displayed by this model. To test this hypothesis, we compared the transepithelial fluxes of
14
C-oxalate,
35
S
O
4
2
-
, and
36
Cl
-
across isolated, short-circuited segments of the distal ileum, cecum, and distal colon from wild-type (WT) and
SAT-1
-KO mice. The absence of
SAT-1
did not impact the transport of these anions by any part of the intestine examined. Additionally,
SAT-1
-KO mice were neither hyperoxaluric nor hyperoxalemic. Instead, 24-h urinary oxalate excretion was almost 50% lower than in WT mice. With no contribution from the intestine, we suggest that this may reflect the loss of
SAT-1
-mediated oxalate efflux from the liver.
SAT-1
-KO mice were, however, profoundly hyposulfatemic, even though there were no changes to intestinal sulfate handling, and the renal clearances of sulfate and creatinine indicated diminished rates of sulfate reabsorption by the proximal tubule. Aside from this distinct sulfate phenotype, we were unable to reproduce the
hyperoxaluria
, hyperoxalemia, and urolithiasis of the original
SAT-1
-KO model. In conclusion, oxalate and sulfate transport by the intestine were not dependent on
SAT-1
, and we found no evidence supporting the long-standing hypothesis that intestinal
SAT-1
contributes to oxalate and sulfate homeostasis. NEW & NOTEWORTHY
SAT-1
is a membrane-bound transport protein expressed in the intestine, liver, and kidney, where it is widely considered essential for the excretion of oxalate, a potentially toxic waste metabolite. Previously, calcium oxalate kidney stone formation by the
SAT-1
-knockout mouse generated the hypothesis that
SAT-1
has a major role in oxalate excretion via the intestine. We definitively tested this proposal and found no evidence for
SAT-1
as an intestinal anion transporter contributing to oxalate homeostasis.
...
PMID:Absence of the sulfate transporter SAT-1 has no impact on oxalate handling by mouse intestine and does not cause hyperoxaluria or hyperoxalemia. 3038 13
