Dawid Krokowski

Yeast ribosomal P0 protein has two separate binding sites for P1/P2 proteins

The ribosome has a distinct lateral protuberance called the stalk; in eukaryotes it is formed by the acidic ribosomal P‐proteins which are organized as a pentameric entity described as P0‐(P1‐P2)2. Bilateral interactions between P0 and P1/P2 proteins have been studied extensively, however, the region on P0 responsible for the binding of P1/P2 proteins has not been precisely defined. Here we report a study which takes the current knowledge of the P0 – P1/P2 protein interaction beyond the recently published information. Using truncated forms of P0 protein and several in vitro and in vivo approaches, we have defined the region between positions 199 and 258 as the P0 protein fragment responsible for the binding of P1/P2 proteins in the yeast Saccharomyces cerevisiae. We show two short amino acid regions of P0 protein located at positions 199–230 and 231–258, to be responsible for independent binding of two dimers, P1A‐P2B and P1B‐P2A respectively. In addition, two elements, the sequence spanning amino acids 199–230 and the P1A‐P2B dimer were found to be essential for stalk formation, indicating that this process is dependent on a balance between the P1A‐P2B dimer and the P0 protein.

A self-defeating anabolic program leads to β-cell apoptosis in endoplasmic reticulum stress-induced diabetes via regulation of amino acid flux

Background: Protein synthesis control is important for β-cell fate during ER stress. Results: Increased protein synthesis during chronic ER stress in β-cells involves the transcriptional induction of an amino acid transporter network. Conclusion: Increased amino acid uptake in β-cells during ER stress promotes apoptosis. Significance: Induced expression of a network of amino acid transporters in islets can contribute to chronic ER stress-induced diabetes. Endoplasmic reticulum (ER) stress-induced responses are associated with the loss of insulin-producing β-cells in type 2 diabetes mellitus. β-Cell survival during ER stress is believed to depend on decreased protein synthesis rates that are mediated via phosphorylation of the translation initiation factor eIF2α. It is reported here that chronic ER stress correlated with increased islet protein synthesis and apoptosis in β-cells in vivo. Paradoxically, chronic ER stress in β-cells induced an anabolic transcription program to overcome translational repression by eIF2α phosphorylation. This program included expression of amino acid transporter and aminoacyl-tRNA synthetase genes downstream of the stress-induced ATF4-mediated transcription program. The anabolic response was associated with increased amino acid flux and charging of tRNAs for branched chain and aromatic amino acids (e.g. leucine and tryptophan), the levels of which are early serum indicators of diabetes. We conclude that regulation of amino acid transport in β-cells during ER stress involves responses leading to increased protein synthesis, which can be protective during acute stress but can lead to apoptosis during chronic stress. These studies suggest that the increased expression of amino acid transporters in islets can serve as early diagnostic biomarkers for the development of diabetes.

Translational Control during Endoplasmic Reticulum Stress beyond Phosphorylation of the Translation Initiation Factor eIF2α

Background: Chronic ER stress suppresses mTORC1 activity. Results: mTORC1-mediated suppression of translation during chronic ER stress is independent of the stress-induced eIF2α-P/ATF4 signaling. Conclusion: The eIF2α-P/ATF4-induced network of amino acid transporters promotes protein synthesis in part by increasing mTORC1-mediated translational control. Significance: The eIF2α-P/ATF4/mTORC1 network controls protein synthesis rates during chronic ER stress and mediates the degree of stress response and survival outcomes. The accumulation of unfolded/misfolded proteins in the endoplasmic reticulum (ER) causes stress to which an unfolded protein response is activated to render cell survival or apoptosis (chronic stress). Transcriptional and translational reprogramming is tightly regulated during the unfolded protein response to ensure specific gene expression. The master regulator of this response is the PERK/eIF2α/ATF4 signaling where eIF2α is phosphorylated (eIF2α-P) by the kinase PERK. This signal leads to global translational shutdown, but it also enables translation of the transcription factor ATF4 mRNA. We showed recently that ATF4 induces an anabolic program through the up-regulation of selected amino acid transporters and aminoacyl-tRNA synthetases. Paradoxically, this anabolic program led cells to apoptosis during chronic ER stress in a manner that involved recovery from stress-induced protein synthesis inhibition. By using eIF2α-P-deficient cells as an experimental system, we identified a communicating network of signaling pathways that contribute to the inhibition of protein synthesis during chronic ER stress. This eIF2α-P-independent network includes (i) inhibition of mammalian target of rapamycin kinase protein complex 1 (mTORC1)-targeted protein phosphorylation, (ii) inhibited translation of a selective group of 5′-terminal oligopyrimidine mRNAs (encoding proteins involved in the translation machinery and translationally controlled by mTORC1 signaling), and (iii) inhibited translation of non-5′-terminal oligopyrimidine ribosomal protein mRNAs and ribosomal RNA biogenesis. We propose that the PERK/eIF2α-P/ATF4 signaling acts as a brake in the decline of protein synthesis during chronic ER stress by positively regulating signaling downstream of the mTORC1 activity. These studies advance our knowledge on the complexity of the communicating signaling pathways in controlling protein synthesis rates during chronic stress.

Pentameric Organization of the Ribosomal Stalk Accelerates Recruitment of Ricin A Chain to the Ribosome for Depurination

Ribosome inactivating proteins (RIPs) depurinate a universally conserved adenine in the α-sarcin/ricin loop (SRL) and inhibit protein synthesis at the translation elongation step. We previously showed that ribosomal stalk is required for depurination of the SRL by ricin toxin A chain (RTA). The interaction between RTA and ribosomes was characterized by a two-step binding model, where the stalk structure could be considered as an important interacting element. Here, using purified yeast ribosomal stalk complexes assembled in vivo, we show a direct interaction between RTA and the isolated stalk complex. Detailed kinetic analysis of these interactions in real time using surface plasmon resonance (SPR) indicated that there is only one type of interaction between RTA and the ribosomal stalk, which represents one of the two binding steps of the interaction with ribosomes. Interactions of RTA with the isolated stalk were relatively insensitive to salt, indicating that nonelectrostatic interactions were dominant. We compared the interaction of RTA with the full pentameric stalk complex containing two pairs of P1/P2 proteins with its interaction with the trimeric stalk complexes containing only one pair of P1/P2 and found that the rate of association of RTA with the pentamer was higher than with either trimer. These results demonstrate that the stalk is the main landing platform for RTA on the ribosome and that pentameric organization of the stalk accelerates recruitment of RTA to the ribosome for depurination. Our results suggest that multiple copies of the stalk proteins might also increase the scavenging ability of the ribosome for the translational GTPases.

Biophysical Properties of the Eukaryotic Ribosomal Stalk

The landing platform for the translational GTPases is located on the 60S ribosomal subunit and is referred to as a GTPase-associated center. The most distinctive feature of this center is an oligomeric complex, the stalk, responsible for the recruitment of translation factors and stimulation of translation factor-dependent GTP hydrolysis. In eukaryotes, the stalk has been investigated in vitro and in vivo, but most information available concerns its individual components only. In the present study, we provide an insight into the biophysical nature of the native stalk isolated from the yeast Saccharomyces cerevisiae. Using fluorescence, circular dichroism, and mass spectrometry analyses, we were able to characterize the natively formed yeast stalk, casting new light on the oligomeric properties of the complex and its quaternary topology, showing that folding and assembly are coupled processes. The pentameric stalk is an exceptionally stable structure with the protein core composed of P0, P1A, and P2B proteins and less tightly bound P1B and P2A capable of dissociating from the stalk core. We obtained also the whole picture of the posttranslational modifications at the logarithmic phase of yeast growth, using mass spectrometry approach, where P proteins are phosphorylated at a single serine residue, P0 may accept two phosphate groups, and P1A none. Additionally, only P1B undergoes N-terminal acetylation after prior methionine removal.

Subcellular localization of ribosomal P0-like protein MRT4 is determined by its N-terminal domain.

The Mrt4 protein, showing extensive sequence similarity to the ribosomal P0 protein, is classified as a ribosomal P0-like protein and acts as a trans-acting factor which modulates the assembly of the pre-60S particle. In this report we investigated the biological nature of the human Mrt4 protein. First, we constructed a series of hybrid hMrt4-P0 proteins by replacing various domains of the P0 protein with corresponding protein fragments from hMrt4. We found that hMrt4 binds to the same site on the large ribosomal subunit as does P0, but despite the sequence homology it is not able to functionally complement the lack of P0. Using fluorescence microscopy and biochemical approaches we also show that hMrt4 occupies predominantly the nucleolar compartment, in contrast to P0 and P1/P2, which are located in the cytoplasm. The nucleolar accumulation of hMrt4 does not depend on a specific nucleolus localization signal, but rather occurs via interaction with established nucleolar components such as rRNA; however, nuclear import of hMrt4 is dependent on a short sequence in the N-terminal part of the protein. Functional analysis with specific inhibitors, actinomycin D and leptomycin B, showed that hMrt4 is a trans-acting factor involved in ribosome maturation, with nucleus-cytoplasm shuttling capacity.

Solution structure of the natively assembled yeast ribosomal stalk determined by small-angle X-ray scattering

The ribosomal stalk of the 60S subunit has been shown to play a crucial role in all steps of protein synthesis, but its structure and exact molecular function remain an unanswered question. In the present study, we show the low-resolution models of the solution structure of the yeast ribosomal stalk, composed of five proteins, P0-(P1-P2)(2). The model of the pentameric stalk complex determined by small-angle X-ray scattering reveals an elongated shape with a maximum length of 13 nm. The model displays three distinct lobes, which may correspond to the individual P1-P2 heterodimers anchored to the C-terminal domain of the P0 protein.

Molecular behavior of human Mrt4 protein, MRTO4, in stress conditions is regulated by its C-terminal region.

Protein Mrt4 is one of trans-acting factors involved in ribosome biogenesis, which in higher eukaryotic cells contains a C-terminal extension similar to the C-terminal part of ribosomal P proteins. We show that human Mrt4 (hMrt4/MRTO4) undergoes phosphorylation in vivo and that serines S229, S233, and S235, placed within its acidic C-termini, have been phosphorylated by CK2 kinase in vitro. Such modification does not alter the subcellular distribution of hMrt4 in standard conditions but affects its molecular behavior during ActD induced nucleolar stress. Thus, we propose a new regulatory element important for the stress response pathway connecting ribosome biogenesis with cellular metabolism.

In vivo formation of Plasmodium falciparum ribosomal stalk — A unique mode of assembly without stable heterodimeric intermediates☆

BACKGROUND The ribosomal stalk composed of P-proteins constitutes a structure on the large ribosomal particle responsible for recruitment of translation factors and stimulation of factor-dependent GTP hydrolysis during translation. The main components of the stalk are P-proteins, which form a pentamer. Despite the conserved basic function of the stalk, the P-proteins do not form a uniform entity, displaying heterogeneity in the primary structure across the eukaryotic lineage. The P-proteins from protozoan parasites are among the most evolutionarily divergent stalk proteins. METHODS We have assembled P-stalk complex of Plasmodium falciparum in vivo in bacterial system using tricistronic expression cassette and provided its characteristics by biochemical and biophysical methods. RESULTS All three individual P-proteins, namely uL10/P0, P1 and P2, are indispensable for acquisition of a stable structure of the P stalk complex and the pentameric uL10/P0-(P1-P2)₂form represents the most favorable architecture for parasite P-proteins. CONCLUSION The formation of P. falciparum P-stalk is driven by trilateral interaction between individual elements which represents unique mode of assembling, without stable P1-P2 heterodimeric intermediate. GENERAL SIGNIFICANCE On the basis of our mass-spectrometry analysis supported by the bacterial two-hybrid assay and biophysical analyses, a unique pathway of the parasite stalk assembling has been proposed. We suggest that the absence of P1/P2 heterodimer, and the formation of a stable pentamer in the presence of all three proteins, indicate a one-step formation to be the main pathway for the vital ribosomal stalk assembly, whereas the P2 homo-oligomer may represent an off-pathway product with physiologically important nonribosomal role.