Laser capture microdissection of intestinal tissue from sea bass larvae using an optimized RNA integrity assay and validated reference genes.

The increasing demand for a sustainable larviculture has promoted research regarding environmental parameters, diseases and nutrition, intersecting at the mucosal surface of the gastrointestinal tract of fish larvae. The combination of laser capture microdissection (LCM) and gene expression experiments allows cell specific expression profiling. This study aimed at optimizing an LCM protocol for intestinal tissue of sea bass larvae. Furthermore, a 3'/5' integrity assay was developed for LCM samples of fish tissue, comprising low RNA concentrations. Furthermore, reliable reference genes for performing qPCR in larval sea bass gene expression studies were identified, as data normalization is critical in gene expression experiments using RT-qPCR. We demonstrate that a careful optimization of the LCM procedure allows recovery of high quality mRNA from defined cell populations in complex intestinal tissues. According to the geNorm and Normfinder algorithms, ef1a, rpl13a, rps18 and faua were the most stable genes to be implemented as reference genes for an appropriate normalization of intestinal tissue from sea bass across a range of experimental settings. The methodology developed here, offers a rapid and valuable approach to characterize cells/tissues in the intestinal tissue of fish larvae and their changes following pathogen exposure, nutritional/environmental changes, probiotic supplementation or a combination thereof.

The Npr1 kinase controls biosynthetic and endocytic sorting of the yeast Gap1 permease.

Membrane trafficking of the general amino acid permease (Gap1) of Saccharomyces cerevisiae is under nitrogen regulation. In cells growing on proline or urea as the sole nitrogen source, newly synthesized Gap1 is delivered to the plasma membrane, where it accumulates. Upon addition of NH(4)(+), a preferential nitrogen source, Gap1 is endocytosed and targeted to the vacuole, where it is degraded. This down-regulation requires ubiquitination of the permease, and this ubiquitination is dependent on the essential Npi1/Rsp5 ubiquitin ligase. In this study, we investigated the role of the Npr1 kinase in the regulation of Gap1 trafficking. We show that Npr1 is required for stabilization of Gap1 at the plasma membrane: when an npr1(ts) mutant growing on proline is shifted to the restrictive temperature, Gap1 down-regulation is triggered, as it is when NH(4)(+) is added to wild-type cells. The fate of newly synthesized Gap1 en route to the plasma membrane is also under Npr1 control: in an npr1Delta mutant, neosynthesized Gap1 is sorted from the Golgi to the vacuole without passing via the plasma membrane. Similar direct sorting of neosynthesized Gap1 to the vacuole was observed in wild-type cells grown on NH(4)(+). Finally, Gap1 is phosphorylated in NPR1 cells, but this phosphorylation is not strictly dependent on Npr1. Our results show that Npr1 kinase plays a central role in the physiological control of Gap1 trafficking and that this control is exerted not only on Gap1 present at the plasma membrane but also on Gap1 late in the secretory pathway. Npr1 belongs to a subgroup of protein kinases, some of which are reported to exert a positive control on the activity of other permeases. We propose that these kinases also function as regulators of permease trafficking.

Ubiquitin is required for sorting to the vacuole of the yeast general amino acid permease, Gap1.

In yeast, ubiquitin plays a central role in proteolysis of a multitude of proteins and serves also as a signal for endocytosis of many plasma membrane proteins. We showed previously that ubiquitination of the general amino acid permease (Gap1) is essential to its endocytosis followed by vacuolar degradation. These processes occur when NH(4)(+), a preferential source of nitrogen, is added to cells growing on proline or urea, i.e. less favored nitrogen sources. In this study, we show that Gap1 is ubiquitinated on two lysine residues in the cytosolic N terminus (positions 9 and 16). A mutant Gap1 in which both lysines are mutated (Gap1(K9K16)) remains fully stable at the plasma membrane after NH(4)(+) addition. Furthermore, each of the two lysines harbors a poly-ubiquitin chain in which ubiquitin is linked to the lysine 63 of the preceding ubiquitin. The Gap1(K9) and Gap1(K16) mutants, in which a single lysine is mutated, are down-regulated in response to NH(4)(+) although more slowly. In proline-grown cells lacking Npr1, a protein kinase involved in the control of Gap1 trafficking, newly synthesized Gap1 is sorted from the Golgi to the vacuole without passing through the plasma membrane (accompanying article, De Craene, J.-O., Soetens, O., and André, B. (2001) J. Biol. Chem. 276, 43939-43948). We show here that ubiquitination of Gap1 is also required for this direct sorting to the vacuole. In an npr1Delta mutant, neosynthesized Gap1(K9K16) is rerouted to and accumulates at the plasma membrane. Finally, Bul1 and Bul2, two proteins interacting with Npi1/Rsp5, are essential to ubiquitination and down-regulation of cell-surface Gap1, as well as to sorting of neosynthesized Gap1 to the vacuole, as occurs in an npr1Delta mutant. Our results reveal a novel role of ubiquitin in the control of Gap1 trafficking, i.e. direct sorting from the late secretory pathway to the vacuole. This result reinforces the growing evidence that ubiquitin plays an important role not only in internalization of plasma membrane proteins but also in their sorting in the endosomes and/or trans-Golgi.

The yeast Npi1/Rsp5 ubiquitin ligase lacking its N-terminal C2 domain is competent for ubiquitination but not for subsequent endocytosis of the gap1 permease.

The yeast ubiquitin ligase Npi1/Rsp5 and its mammalian homologue Nedd4 are involved in ubiquitination of various cell surface proteins, these being subsequently internalized by endocytosis and degraded in the vacuole/lysosome. Both enzymes consist of an N-terminal C2 domain, three to four successive WW(P) domains, and a C-terminal catalytic domain (HECT) containing a highly conserved cysteine residue involved in ubiquitin thioester formation. In this study, we show that the conserved cysteine of the HECT domain is required for yeast cell viability and for ubiquitination and subsequent endocytosis of the Gap1 permease. In contrast, the C2 domain of Npi1/Rsp5 is not essential to cell viability. Its deletion impairs internalization of Gap1, without detectably affecting ubiquitination of the permease. This suggests that Npi1/Rsp5 participates, via its C2 domain, in endocytosis of ubiquitinated permeases.

Amino acid signaling in Saccharomyces cerevisiae: a permease-like sensor of external amino acids and F-Box protein Grr1p are required for transcriptional induction of the AGP1 gene, which encodes a broad-specificity amino acid permease.

The SSY1 gene of Saccharomyces cerevisiae encodes a member of a large family of amino acid permeases. Compared to the 17 other proteins of this family, however, Ssy1p displays unusual structural features reminiscent of those distinguishing the Snf3p and Rgt2p glucose sensors from the other proteins of the sugar transporter family. We show here that SSY1 is required for transcriptional induction, in response to multiple amino acids, of the AGP1 gene encoding a low-affinity, broad-specificity amino acid permease. Total noninduction of the AGP1 gene in the ssy1Delta mutant is not due to impaired incorporation of inducing amino acids. Conversely, AGP1 is strongly induced by tryptophan in a mutant strain largely deficient in tryptophan uptake, but it remains unexpressed in a mutant that accumulates high levels of tryptophan endogenously. Induction of AGP1 requires Uga35p(Dal81p/DurLp), a transcription factor of the Cys6-Zn2 family previously shown to participate in several nitrogen induction pathways. Induction of AGP1 by amino acids also requires Grr1p, the F-box protein of the SCFGrr1 ubiquitin-protein ligase complex also required for transduction of the glucose signal generated by the Snf3p and Rgt2p glucose sensors. Systematic analysis of amino acid permease genes showed that Ssy1p is involved in transcriptional induction of at least five genes in addition to AGP1. Our results show that the amino acid permease homologue Ssy1p is a sensor of external amino acids, coupling availability of amino acids to transcriptional events. The essential role of Grr1p in this amino acid signaling pathway lends further support to the hypothesis that this protein participates in integrating nutrient availability with the cell cycle.