Expression of the vasopressin and oxytocin genes in human hypothalami.

Poly(A)+ RNA isolated from post-mortem human hypothalami has been used to characterize the poly-protein precursors to vasopressin and oxytocin. Translation in a cell-free system and subsequent immuno-precipitation with antibodies raised against either vasopressin or neurophysin identified a product of Mr 19000 (prepro-vasopressin). A second less intense product of Mr 16500 was tentatively identified as prepro-oxytocin. A cDNA library derived from the human hypothalamic poly(A)+ RNA was screened for vasopressin and oxytocin-encoding cDNA using heterologous probes; clones encoding the two precursors were identified and found to be organized as their rat and bovine counterparts. Northern blot analysis shows that the mRNAs for the two prepro-hormones consist of approximately 840 (AVP) and approximately 700 (OT) nucleotides.

The neurohypophyseal hormones vasopressin and oxytocin. Precursor structure, synthesis and regulation.

Complete cDNA sequences for the vasopressin and oxytocin precursor polyproteins have been determined for the rat, calf, human and pig (vasopressin only), indicating the essential conservation of the precursor structures throughout mammals. DNA probes specific for vasopressin or oxytocin mRNAs have been used to identify both classic (hypothalamic) and novel (thymus, corpus luteum, phaeochromocytoma) sites of hormone expression. Semiquantitative DNA/RNA hybridization suggests that in rats expression of the vasopressin and oxytocin genes is positively effected by osmotic stress, negatively by a systemically applied excess of vasopressin; in the latter experiment a reduction in the hypothalamic levels of vasopressin and oxytocin mRNAs in normal and Brattleboro rats have been observed. This suggests a feedback regulation by the hormone as a possible element in controlling the transcription of the vasopressin gene.

Analysis of a dystrophin gene deletion by amplification of mRNA isolated from DMD myotubes cultured in vitro.

The most frequent causes for the X-linked muscular dystrophy of the allelic Duchenne (DMD) or Becker (BMD) type are partial deletions of the dystrophin gene. These mutations are accompanied either by disrupted or by preserved translational reading frames in mRNAs derived from the deleted genes. As a rule, the reading frame is destroyed in the more severe DMD, whereas it is preserved in the less severe BMD (M. Koenig et al., 1989, Am. J. Hum. Genet. 45, 498-506). We have analyzed in detail a deletion that was detected in a fetus at risk of DMD. The analysis of this mutation included the delineation of the altered subregion in the dystrophin mRNA. mRNA was isolated from myotubes derived from embryonic DMD myoblasts propagated in vitro. This study was based on enzymatic amplification by the polymerase chain reaction (PCR) of dystrophin mRNA and direct sequencing of the amplified cDNA. Exons 47 to 50 were found to be missing in the mRNA. The splicing of exon 46 to exon 51 resulted in a reading frameshift, indicating that this mutation is likely to be responsible for a DMD type of dystrophy. The clinical diagnosis of DMD for a 10-year-old patient in this family was compatible with the "reading frame" assumption.