Pri sORF peptides induce selective proteasome-mediated protein processing.

A wide variety of RNAs encode small open-reading-frame (smORF/sORF) peptides, but their functions are largely unknown. Here, we show that Drosophila polished-rice (pri) sORF peptides trigger proteasome-mediated protein processing, converting the Shavenbaby (Svb) transcription repressor into a shorter activator. A genome-wide RNA interference screen identifies an E2-E3 ubiquitin-conjugating complex, UbcD6-Ubr3, which targets Svb to the proteasome in a pri-dependent manner. Upon interaction with Ubr3, Pri peptides promote the binding of Ubr3 to Svb. Ubr3 can then ubiquitinate the Svb N terminus, which is degraded by the proteasome. The C-terminal domains protect Svb from complete degradation and ensure appropriate processing. Our data show that Pri peptides control selectivity of Ubr3 binding, which suggests that the family of sORF peptides may contain an extended repertoire of protein regulators.

In situ reverse transcription-polymerase chain reaction. Applications for light and electron microscopy.

Since its discovery in 1986 by Mullis, the polymerase chain reaction (PCR) has been extensively developed by morphologists in order to overcome the main limitation of in situ hybridization, the lack of sensitivity. In situ PCR combines the extreme sensitivity of PCR with the cell-localizing ability of in situ hybridization. The amplification of DNA (PCR) or a cDNA (RT-PCR) in cell or tissue sections has been developed at light and electron microscopic levels. A successful PCR experiment requires the careful optimization of several parameters depending on the tissue (or of cell types), and a compromise must be found between the fixation time, pretreatments and a good preservation of the morphology. Other crucial factors (primer design, concentration in MgCl2, annealing and elongation temperatures during the amplification steps) and their influence on the specificity and sensitivity of in situ PCR or RT-PCR are discussed. The necessity to run appropriate controls, especially to assess the lack of diffusion of the amplified products, is stressed. Current applications and future trends are also presented.

The three subtypes of atrial natriuretic peptide (ANP) receptors are expressed in the rat adrenal gland.

Atrial natriuretic peptide (ANP) actions are mediated by highly selective and specific receptors. Three subtypes have been characterized and cloned: ANP receptor-A (or GC-A), -B (or GC-B) and -C (the so-called clearance receptor). In rat adrenal gland, the mRNA for each subtype was detected using 35S-dUTP or digoxigenin-11-dUTP specific labeled probes, and in situ hybridization at light and electron microscopic levels respectively. The three subtypes were expressed the most abundantly in the zona glomerulosa. The amount of GC-A mRNA expression, quantified using macro-autoradiography and densitometry, was higher than the amounts of GC-B mRNA and ANPR-C mRNA both in zona glomerulosa and medullary of adrenal gland. At electron microscopic level, the three subtypes of ANPR were revealed in glomerulosa cells. A noticeable signal was also present in the medullary area, especially for GC-A mRNA, in adrenaline-containing chromaffin cells. No signal was detected in noradrenaline-containing chromaffin cells. The subcellular localization of the three mRNAs is similar: in the cytoplasmic matrix and in the euchromatin of the nucleus in each cell of glomerulosa, and in the same compartments of the adrenaline-containing chromaffin cells. These data indicate that the adrenal gland is an important target tissue for ANP action both in glomerulosa cells and adrenaline-containing chromaffin cells. The mRNA expression levels were different for each ANPR subtype.

Constitutive nuclear localization of Janus kinases 1 and 2.

Both GH and the GH receptor have been reported to undergo rapid nuclear translocation. Janus kinases (JAK) 1 and 2 have been implicated in GH receptor signaling, and both of these kinases are phosphorylated by GH stimulation. In this report, we have investigated the subcellular distribution of JAK1 and JAK2. Both JAK1 and JAK2 exhibit a nucleocytoplasmic distribution by immunocytochemistry in unstimulated serum deprived CHO cells stably transfected with rat GH receptor complementary DNA (cDNA). The nucleocytoplasmic localization of JAK2 was verified by immunogold electron microscopy in both rat liver hepatocytes and CHO cells stably transfected with rat GH receptor cDNA. Nucleocytoplasmic localization of JAK2 was also verified by transient tranfection of CHO cells with a Haemophilus influenzae haemagglutinin (HA) epitope tagged JAK2 expression plasmid and subsequent localization of HA immunoreactivity. Western blot analysis of purified nuclear extracts revealed the presence of immunoreactive JAK1 at 130 kDa and immunoreactive JAK2 at 128 kDa. No change in the nuclear content of JAK1 or JAK2 was observed upon ligand stimulation of GH receptor cDNA transfected cells with 100 nM human GH for 5, 10, 15, 30, or 60 min. GH stimulation caused, however, the appearance of tyrosine phosphorylated 42- and 44-kDa proteins as well as tyrosine phosphorylated JAK2 in the nucleus. The constitutive nuclear localization of the Janus Kinases is suggestive of a novel nuclear role for JAK family members, in addition to their described cytosolic function and presents an interesting challenge to the subcellular site of hormone action.

Ultrastructural expression of prolactin receptor in rat liver.

Prolactin (PRL) is a trophic hormone which acts mainly at the plasma membrane level of hepatocyte. The mechanisms involved in the transduction of the signal after binding of PRL to its receptors are not yet well documented. In the present study we have examined the subcellular patterns of PRL receptor expression in rat liver by ultrastructural in situ hybridization and immunocytology. In situ hybridization was performed using digoxigenin-labeled oligonucleotide probes revealed by indirect immunogold reaction. The expression of both the long and short forms of PRL-receptor mRNA was readily identified in the cytoplasmic matrix, and in association with the endoplasmic reticulum, but a low expression of these forms was detected in the nucleus of hepatocyte. Moreover, this expression appeared clearly higher in female rather than in male hepatocytes. On the other hand, immunogold detection of PRL-receptor protein was performed using two monoclonal antibodies (U5 and T6), specific to the extracellular domain of the PRL-receptor. Indirect immunocytological detection confirmed the presence of PRL receptor-like immunoreactivity at the level of the plasma membrane, and in the cytoplasmic matrix associated or not with endocytotic vesicles, the endoplasmic reticulum, the peroxisomes, the Golgi complex, and the nuclei of both male and female hepatocytes. No clear difference was found between U5 and T6 mAbs, with regard to the subcellular localization. These results show the distribution of both PRL-receptor mRNA and PRL receptor protein in numerous subcellular compartments of hepatocyte, and evidence that these compartments are involved in the early stage of the PRL action.