A mouse model of hereditary folate malabsorption: deletion of the PCFT gene leads to systemic folate deficiency.

The human proton coupled folate transporter (PCFT) is involved in low pH-dependent intestinal folate transport. In this report, we describe a new murine model of the hereditary folate malabsorption syndrome that we developed through targeted disruption of the first 3 coding exons of the murine homolog of the PCFT gene. By 4 weeks of age, PCFT-deficient (PCFT(-/-)) mice developed severe macrocytic normochromic anemia and pancytopenia. Immature erythroblasts accumulated in the bone marrow and spleen of PCFT(-/-) mice and failed to differentiate further, showing an increased rate of apoptosis in intermediate erythroblasts and reduced release of reticulocytes. In response to the inefficient hematologic development, the serum of the PCFT(-/-) animals contained elevated concentrations of erythropoietin, soluble transferrin receptor (sCD71), and thrombopoietin. In vivo folate uptake experiments demonstrated a systemic folate deficiency caused by disruption of PCFT-mediated intestinal folate uptake, thus confirming in vivo a critical and nonredundant role of the PCFT protein in intestinal folate transport and erythropoiesis. The PCFT-deficient mouse serves as a model for the hereditary folate malabsorption syndrome and is the most accurate animal model of folate deficiency anemia described to date that closely captures the spectrum of pathology typical of this disease.

Substituted cysteine accessibility method analysis of human concentrative nucleoside transporter hCNT3 reveals a novel discontinuous region of functional importance within the CNT family motif (G/A)XKX3NEFVA(Y/M/F).

The human SLC28 family of integral membrane CNT (concentrative nucleoside transporter) proteins has three members, hCNT1, hCNT2, and hCNT3. Na(+)-coupled hCNT1 and hCNT2 transport pyrimidine and purine nucleosides, respectively, whereas hCNT3 mediates transport of both pyrimidine and purine nucleosides utilizing Na(+) and/or H(+) electrochemical gradients. These and other eukaryote CNTs are currently defined by a putative 13-transmembrane helix (TM) topology model with an intracellular N terminus and a glycosylated extracellular C terminus. Recent mutagenesis studies, however, have provided evidence supporting an alternative 15-TM membrane architecture. In the absence of CNT crystal structures, valuable information can be gained about residue localization and function using substituted cysteine accessibility method analysis with thiol-reactive reagents, such as p-chloromercuribenzene sulfonate. Using heterologous expression in Xenopus oocytes and the cysteineless hCNT3 protein hCNT3C-, substituted cysteine accessibility method analysis with p-chloromercuribenzene sulfonate was performed on the TM 11-13 region, including bridging extramembranous loops. The results identified residues of functional importance and, consistent with a new revised 15-TM CNT membrane architecture, suggest a novel membrane-associated topology for a region of the protein (TM 11A) that includes the highly conserved CNT family motif (G/A)XKX(3)NEFVA(Y/M/F).

A proton-mediated conformational shift identifies a mobile pore-lining cysteine residue (Cys-561) in human concentrative nucleoside transporter 3.

The concentrative nucleoside transporter (CNT) protein family in humans is represented by three members, hCNT1, hCNT2, and hCNT3. Belonging to a CNT subfamily phylogenetically distinct from hCNT1/2, hCNT3 mediates transport of a broad range of purine and pyrimidine nucleosides and nucleoside drugs, whereas hCNT1 and hCNT2 are pyrimidine and purine nucleoside-selective, respectively. All three hCNTs are Na(+)-coupled. Unlike hCNT1/2, however, hCNT3 is also capable of H(+)-mediated nucleoside cotransport. Using site-directed mutagenesis in combination with heterologous expression in Xenopus oocytes, we have identified a C-terminal intramembranous cysteine residue of hCNT3 (Cys-561) that reversibly binds the hydrophilic thiol-reactive reagent p-chloromercuribenzene sulfonate (PCMBS). Access of this membrane-impermeant probe to Cys-561, as determined by inhibition of hCNT3 transport activity, required H(+), but not Na(+), and was blocked by extracellular uridine. Although this cysteine residue is also present in hCNT1 and hCNT2, neither transporter was affected by PCMBS. We conclude that Cys-561 is located in the translocation pore in a mobile region within or closely adjacent to the nucleoside binding pocket and that access of PCMBS to this residue reports a specific H(+)-induced conformational state of the protein.

Two zinc-cluster transcription factors control induction of alternative oxidase in Neurospora crassa.

The alternative oxidase transfers electrons from ubiquinol to molecular oxygen, providing a mechanism for bypassing the later steps of the standard cytochrome-mediated electron transport chain. The enzyme is found in an array of organisms and in many cases is known to be produced in response to perturbations of the standard chain. Alternative oxidase is encoded in the nucleus but functions in the inner mitochondrial membrane. This implies the existence of a retrograde regulation pathway for communicating from the mitochondrion to the nucleus to induce alternative oxidase expression. Previous studies on alternative oxidase in fungi and plants have shown that a number of genes are required for expression of the enzyme, but the identity of these genes has remained elusive. By gene rescue we have now shown that the aod-2 and aod-5 genes of Neurospora crassa encode transcription factors of the zinc-cluster family. Electrophoretic mobility shift assays show that the DNA-binding domains of the AOD2 and AOD5 proteins act in tandem to bind a sequence element in the alternative oxidase gene promoter that is required for expression. Both proteins contain potential PAS domains near their C terminus, which are found primarily in proteins involved in signal transduction.

Identification of an alternative oxidase induction motif in the promoter region of the aod-1 gene in Neurospora crassa.

The nuclear aod-1 gene of Neurospora crassa encodes the alternative oxidase and is induced when the standard cytochrome-mediated respiratory chain of mitochondria is inhibited. To study elements of the pathway responsible for alternative oxidase induction, we generated a series of mutations in the region upstream from the aod-1 structural gene and transformed the constructs into an aod-1 mutant strain. Transformed conidia were plated on media containing antimycin A, which inhibits the cytochrome-mediated electron transport chain so that only cells expressing alternative oxidase will grow. Using this functional in vivo assay, we identified an alternative oxidase induction motif (AIM) that is required for efficient expression of aod-1. The AIM sequence consists of two CGG repeats separated by 7 bp and is similar to sequences known to be bound by members of the Zn(II)2Cys6 binuclear cluster family of transcription factors. The AIM motif appears to be conserved in other species found in the order Sordariales.