Mutational analysis of the PHEX gene: novel point mutations and detection of large deletions by MLPA in patients with X-linked hypophosphatemic rickets.

X-Linked hypophosphatemic rickets (HYP, XLH) is a disorder of phosphate homeostasis, characterized by renal phosphate wasting and hypophosphatemia, with normal to low 1,25-dihydroxy vitamin D3 serum levels. The purpose of our study was the detection of inactivating mutations in the PHEX gene, the key enzyme in the pathogenesis of XLH. The 16 patients, representing eight families, presented with suspected XLH from biochemical and clinical evidence. All 16 were referred for mutational analysis of the PHEX gene. We detected three novel disease-causing mutations, C59S, Q394X, and W602, for which a loss of function can be predicted. A G28S variation, found in two healthy probands, may be a rare polymorphism. Another mutation, A363 V, is localized on the same allele as the C59S mutation, thus its functional consequences cannot be proven. Furthermore, we detected a deletion of three nucleotides in exon 15 which resulted in the loss of amino acid threonine 535. Heterozygosity of this mutation in a male patient without any chromosomal aberrations suggests its presence as a mosaic. Novel large deletions were detected using multiplex ligation-dependent probe amplification (MLPA) analysis. Two of these deletions, loss of exon 22 alone or exons 21 and 22 together, may result in the translation of a C-terminal truncated protein. Two large deletions comprise exons 1-9 and exons 4-20, respectively, and presumably result in a nonfunctional protein. We conclude that molecular genetic analysis confirms the clinical diagnosis of XLH and should include sequence analysis as well as the search for large deletions, which is facilitated by MLPA.

Changes of AT(2) receptor levels in the rat adrenal cortex and medulla induced by bilateral nephrectomy and its modulation by circulating ANG II.

We studied regulation of the AT(2) receptor by investigating the effect of bilateral nephrectomy (bNX) in Sprague-Dawley rats. The expression of aldosterone synthase (CYP11B2) and AT(2) receptor mRNA was detected by nonradioactive in situ hybridization. AT(2) receptor mRNA was detected in cells of the first two or three subcapsular cell layers of the zona glomerulosa (ZG) and in the medulla of sham-operated animals. After bNX, the number and area of distribution of AT(2) receptor-positive cells increased in the ZG. This was associated with an enlargement of the steroidogenic active ZG and with reduced proliferation rate (sham 5.9 +/- 0.9%; bNX 2.4 +/- 0.2%; p<0.02). Infusion of angiotensin II (ANG II; 200 ng/kg/min SC for 56 hr) to bNX rats did not reverse the effect of nephrectomy on the distribution of AT(2) receptor expression, although mRNA levels per cell were reduced compared to NX alone. ANG II infusion decreased proliferation rate further (0.4 +/- 0.07%; p<0.001). In the adrenal medulla after bNX, decreased expression of the AT(2) receptor was associated with increased proliferation (2.6 +/- 0.2% vs 6.6 +/- 0.5%). These results demonstrate differential regulation of the AT(2) receptor in the adrenal gland and suggest that expression of the AT(2) receptor is involved in regulating proliferation and differentiation in the ZG and medulla. (J Histochem Cytochem 49:649-656, 2001)

Tissue-specific expression of a rat renin transcript lacking the coding sequence for the prefragment and its stimulation by myocardial infarction.

An alternative transcript of the rat renin gene was recently characterized in the adrenal gland, in addition to the known messenger RNA (mRNA) coding for preprorenin. In the alternative transcript, exon 1 is replaced by exon 1A, a domain originating in intron 1. The reading frame of this mRNA, termed exon 1A-renin transcript, codes for a truncated prorenin that presumably remains intracellular, in contrast to preprorenin, which is targeted to the secretory pathway by its prefragment. We here demonstrate the tissue-specific regulation of expression of both transcripts by RT and PCR. In many tissues both transcripts are present, for example in the adrenal gland, spleen, liver, and hypothalamus. In some organs, however, only one of the renin mRNAs is found. In the kidney only the full-length mRNA coding for preprorenin is detected. In the heart exclusively the exon 1A-mRNA is expressed, but not the preprorenin transcript. After myocardial infarction, which is known to activate the intracardiac renin-angiotensin system, expression of exon 1A-renin mRNA in the left ventricle was stimulated about 4-fold, compared with that in sham-operated animals, whereas no mRNA corresponding to preprorenin was detectable. These findings may have implications for the current concepts of local extrarenal renin-angiotensin systems, as they provide the molecular basis for a possible intracellular function of renin and exclude a role for locally produced secretory renin in the heart.

An alternative transcript of the rat renin gene can result in a truncated prorenin that is transported into adrenal mitochondria.

Characterization of the local renin-angiotensin system in the rat adrenal zona glomerulosa indicated a dual targeting of renin both to the secretory pathway and mitochondria. To investigate the transport of renin into mitochondria, we constructed a series of amino-terminal deletion variants of preprorenin. One of these variants, lacking the complete signal sequence for the endoplasmic reticulum and 10 amino acids of the profragment, was transported efficiently into isolated mitochondria. The transport was further shown to be dependent on mitochondrial membrane potential and ATP synthesis. Analysis of adrenal RNA revealed the existence of 2 renin transcripts. While one of the transcripts corresponds to the known full-length transcript, the other one lacks exon 1; instead, exon 2 is preceded by a domain of 80 nucleotides originating from intron 1. This domain, as well as the following region of intron 1 being excised, shows all essential sequence elements defining an additional, so-far-unknown exon. The second mRNA possibly derives from an additional transcription start in intron 1 and an alternative splicing process. Translation of this mRNA could result in a truncated prorenin representing a cytosolic form of renin, which is required for transport into mitochondria. This truncated prorenin corresponds exactly to the deletion variant being imported into mitochondria in vitro.

Specific regulation of StAR expression in the rat adrenal zona glomerulosa. An in situ hybridization study.

Steroid acute regulatory protein (StAR) plays an essential role in steroidogenesis because it is responsible for the transfer of cholesterol from cellular stores to the inner mitochondrial membrane. We investigated the distribution and regulation of StAR expression in association with aldosterone production in the rat adrenal gland in vivo. Using nonradioactive in situ hybridization, we demonstrate that the outermost five to seven parenchymal cell layers express the StAR gene only weakly and inhomogeneously. The strongest expression is found in the zona fasciculata and zona reticularis. In addition, some cells in the adrenal medulla also stained positively. To differentiate between functionally active glomerulosa and inactive intermediate cells, we compared the expression pattern of StAR with that of aldosterone synthase. The expression of the latter is localized to two or three cell layers only, located immediately below the capsule. However, the cells of the intermedia are capable of expressing both genes prominently, as shown after stimulation with bilateral nephrectomy for 2 days. All zones of the adrenal cortex by then expressed StAR gene to the same extent. This was accompanied by a 50-fold elevated plasma aldosterone concentration. Our data demonstrate that the width of the aldosterone-producing zone can increase within a short period of time by recruiting hormonally inactive cells to steroidogenesis.

Protein import into chloroplasts. The hydrophilic lumenal proteins exhibit unexpected import and sorting specificities in spite of structurally conserved transit peptides.

Plastocyanin and the 16-, 23-, and 33-kDa polypeptides of the oxygen-evolving complex associated with photosystem II are hydrophilic, nuclear encoded components of the photosynthetic machinery that are all located in the lumen of thylakoid membranes. All four proteins are therefore imported into chloroplasts and, in addition, translocated across the thylakoid membrane. They share functionally equivalent, bipartite transit peptides, which are removed in two steps during or after import into the organelle and translocation across the thylakoid membrane, respectively. The transit peptides lack any homology at the sequence level but possess remarkably similar predicted secondary structures. We have studied the targeting potential of the authentic precursor molecules and all possible chimeric combinations generated by a specific, commonly applicable cassette system, which facilitates codon-correct reciprocal exchanges of transit peptides and mature parts. An unexpected specificity of import and sorting processes was found. All constructs can be imported into the organelle, though with greatly differing efficiency. On the other hand, the lumen-targeting parts are essential but not in all cases sufficient for correct intraorganellar routing. This implies that translocation across the thylakoid membrane appears not to depend merely on simple interactions of charged or hydrophobic regions between protein and membrane but requires an additional quality of information that includes the functional co-evolution of a transit peptide with its mature protein. Signaling and sorting appear to be essential at almost every step of the entire process for proper traffic regulation since distinct steps can be impaired (rate-limiting or arrested) in the individual combinations: the transfer across the envelope membranes (e.g. 16/PC) and the interaction with (e.g. 16/33) or the translocation across the thylakoid membrane (e.g. 33/23).

Nucleotide sequence of cDNAs encoding the entire precursor polypeptide for thioredoxin m from spinach chloroplasts.

Using the expression vector lambda gt11 and immunochemical detection, six cDNA clones that encode the entire precursor polypeptides for spinach thioredoxin m were isolated and characterized. The ca. 1.0 kb cDNA sequence of the largest clone hybridizes to an RNA species of 1.1 kb. In each instance the cDNA sequences display single open reading frames encoding polypeptides of 181 amino acid residues corresponding to a molecular mass of 19.8 kDa. The sequences of the independently selected cDNAs fall into two classes that are indicative of at least two (closely related) genes for this protein. The amino acid sequences deduced from the cDNA sequences differ to some extent from the amino acid sequence published for spinach thioredoxin m. The sequences predict identical mature proteins of 112-114 amino acids corresponding to a polypeptide molecular mass of ca. 12.4-12.6 kDa, and include stroma-targeting N-terminal transit peptides of 67 residues which are removed during or after import into the organelle. Precursor protein was made in vitro from each of the different cDNA clones and imported into isolated intact chloroplasts. Independent of the cDNA clone used, two isoforms were detected in the chloroplasts after import in each instance. They comigrated with authentic thioredoxin mb and mc. These results indicate that the size variants observed for this protein in vivo result from post-translational modification and do not originate in different genes.