Translational control during mitosis

Translation is now recognized as an important process in the regulation of gene expression. During the cell cycle, translation is tightly regulated. Protein synthesis is necessary for entry into and progression through mitosis and conversely, modifications of translational activity are observed during the cell cycle. This review focuses on translational control during mitosis (or M-phase) and the role of CDK1/cyclin B, the universal cell cycle regulator implicated in the G2/M transition, in protein synthesis regulation.     

Gene-specific regulation by general translation factors

Protein synthesis is the ultimate step of gene expression and a key control point for regulation. In particular, it enables cells to rapidly manipulate protein production without new mRNA synthesis, processing, or export. Recent studies have enhanced our understanding of the translation initiation process and helped elucidate how modifications of the general translational machinery regulate gene-specific protein production.     

Regucalcin as a potential biomarker for metabolic and neuronal diseases

Regucalcin was initially discovered in 1978 as a regulatory protein in calcium signaling. The regucalcin gene, which is localized on the X chromosome, is found in vertebrate and invertebrate species. Regucalcin has been shown to play a pivotal role in cell regulation: maintaining of intracellular calcium homeostasis, suppressions of signal transduction, inhibition of translational protein synthesis, nuclear deoxyribonucleic acid (DNA) and ribonucleic acid (RNA) synthesis, regulation of gene expression, and anti-effects on proliferation and apoptosis in many cell types. The expression of the regucalcin gene and its protein has been shown to alter with various metabolic diseases, and regucalcin plays an important role in the development of many pathophysiologic states. Serum regucalcin has been found to increase with liver injury, and also urinary regucalcin is elevated with kidney damage, suggesting a useful tool as biomarker for diagnosis. Moreover, regucalcin has been shown to be good tool in early diagnosis for Alzheimer’s disease and other brain diseases. This review will discuss a significance of regucalcin as a clinical biomarker in various diseases.     

Model of cap‐dependent translation initiation in sea urchin: A step towards the eukaryotic translation regulation network

The large and rapid increase in the rate of protein synthesis following fertilization of the sea urchin egg has long been a paradigm of translational control, an important component of the regulation of gene expression in cells. This translational up‐regulation is linked to physiological changes that occur upon fertilization and is necessary for entry into first cell division cycle. Accumulated knowledge on cap‐dependent initiation of translation makes it suited and timely to start integrating the data into a system view of biological functions. Using a programming environment for system biology coupled with model validation (named Biocham), we have built an integrative model for cap‐dependent initiation of translation. The model is described by abstract rules. It contains 51 reactions involved in 74 molecular complexes. The model proved to be coherent with existing knowledge by using queries based on computational tree logic (CTL) as well as Boolean simulations. The model could simulate the change in translation occurring at fertilization in the sea urchin model. It could also be coupled with an existing model designed for cell‐cycle control. Therefore, the cap‐dependent translation initiation model can be considered a first step towards the eukaryotic translation regulation network. Mol. Reprod. Dev. 77: 257–264, 2010. © 2009 Wiley‐Liss, Inc.     

Messenger RNAs in dendrites: localization,stability, and implications for neuronal function

In the mammalian central nervous system (CNS), each neuron receives signals from other neurons through numerous synapses located on its cell body and dendrites. Molecules involved in the postsynaptic signaling pathways need to be targeted to the appropriate subcellular domains at the right time during both synaptogenesis and the maintenance of synaptic functions. The presence of messenger RNAs (mRNAs) in dendrites offers a mechanism for synthesizing the appropriate molecules at the right place in response to local extracellular stimuli. Several dendritic mRNAs have been identified, and the mechanisms controlling their localization are beginning to be understood. In many cell types, controls on mRNA stability play an important role in the regulation of gene expression, but it is unclear to what extent this type of control operates in dendrites. The regulation of protein synthesis and the control of mRNA stability in dendrites could have important implications for neuronal function. BioEssays 20:70–78, 1998. © 1998 John Wiley & Sons, Inc.     

Initiation factors eIF4: from sea urchin embryonic development to chronic lymphocytic leukemia

mRNA translation is now recognized as a important regulatory step for gene expression in different physiological and pathophysiological processes including cell proliferation and apoptosis. B-cell chronic lymphocytic leukemia (B-CLL) is characterized by the accumulation of resting lymphocytes and defective apoptosis. The mRNA cap-binding protein eIF4E (eukaryotic Initiation Factor 4E) and its repressor 4E-BP (eIF4E Binding protein) are crucial translational regulators that have been involved in survival and apoptosis processes of cells. We have shown that the release of eIF4E from its translational repressor 4E-BP is an important event for the first mitotic division triggered by fertilization and that the degradation of 4E-BP is a new means to regulate 4E-BP function that has to be analyzed in other physiological and physiopathological processes. In this chapter, we describe recent advances illustrating the importance of eIF4E and 4E-BP in cancer processes, suggesting that these actors can be targeted for potential therapy against cancer in general and LLC in particular.     

Novel G-protein complex whose requirement is linked to the translational status of the cell

G proteins, which bind and hydrolyze GTP, are involved in regulating a variety of critical cellular processes, including the process of protein synthesis. Many members of the subfamily of elongation factor class G proteins interact with the ribosome and function to regulate discrete steps during the process of protein synthesis. Despite sequence similarity to factors involved in translation, a role for the yeast Hbs1 protein has not been defined. In this work we have identified a genetic relationship between genes encoding components of the translational apparatus and HBS1. HBS1, while not essential for viability, is important for efficient growth and protein synthesis under conditions of limiting translation initiation. The identification of an Hbs1p-interacting factor, Dom34p, which shares a similar genetic relationship with components of the translational apparatus, suggests that Hbs1p and Dom34p may function as part of a complex that facilitates gene expression. Dom34p contains an RNA binding motif present in several ribosomal proteins and factors that regulate translation of specific mRNAs. Thus, Hbs1p and Dom34p may function together to help directly or indirectly facilitate the expression either of specific mRNAs or under certain cellular conditions.     

Profiling of gene-dependent translational progress in cell-free protein synthesis by real-space imaging

In general, gene-dependent translational progress affects the efficiency of protein expression. To evaluate the translational progress of protein synthesis, it is necessary to trace the time course of translation as well as the quantity of products. Here we present a new method for tracking translation steps in cell-free protein synthesis using atomic force microscopy (AFM). The cell-free protein synthesis system is useful to track the inherent translational progress of a target gene, whereas conventional UV absorption measurement coupled with density gradient fractionation is difficult to analyze such small sample quantities. Because the high resolution of AFM enables us to clearly count the number of ribosomes included in polysomes, polysome profiles can be obtained directly without complicated fractionation. With this method, we could elucidate the detailed polysome profile with only 1 μl of sample solution. We observed the translational progress of green fluorescent protein synthesis, a model of high-expression protein, as well as human retinoid X receptor. Detailed polysome profiles showed different patterns of translational progress and were clearly associated with the results of time-dependent protein expression. Our study suggests the possibility for comprehensive character analysis of inherent gene-dependent translational progress.     

Dynamic Model of the Process of Protein Synthesis in Eukaryotic Cells

Protein synthesis is the final step of gene expression in all cells. In order to understand the regulation of this process, it is important to have an accurate model that incorporates the regulatory steps. The model presented in this paper is composed of set of differential equations which describe the dynamics of the initiation process and its control, as well as peptide elongation, starting with the amino acids available for peptide creation. A novel approach for modeling the elongation process permits useful prediction of protein production and consumption of energy and amino acids, as well as ribosome loading rate and ribosome spacing on the mRNA. An erratum to this article can be found at     

Biochemical mechanisms for translational regulation in synaptic plasticity

Changes in gene expression are required for long-lasting synaptic plasticity and long-term memory in both invertebrates and vertebrates. Regulation of local protein synthesis allows synapses to control synaptic strength independently of messenger RNA synthesis in the cell body. Recent reports indicate that several biochemical signalling cascades couple neurotransmitter and neurotrophin receptors to translational regulatory factors in protein synthesis-dependent forms of synaptic plasticity and memory. In this review, we highlight these translational regulatory mechanisms and the signalling pathways that govern the expression of synaptic plasticity in response to specific types of neuronal stimulation.