Small heat shock proteins are differentially regulated during pollen development and following heat stress in tobacco

In plants small heat shock proteins (sHsp) are abundantly expressed upon heat stress in vegetative tissue, however, sHsp expression is also developmentally induced in pollen. The developmental induction of sHsp has been related to the potential for stress-induced microspore embryogenesis. We investigated the polymorphism among sHsp and their expression during pollen development and after heat stress in tobacco. Real-time RT-PCR was used for quantification of mRNA of two known and nine newly isolated cDNAs representing cytosolic sHsp. At normal temperature most of these genes are not transcribed in vegetative tissues, however, all genes were expressed during pollen development. Low levels of mRNAs were found for sHsp-1A and -1B in early-unicellular stage, increasing four to sevenfold in mature pollen. Nine other genes are up-regulated in unicellular and down-regulated in bicellular pollen; three these genes show stage-specific expression. Western analysis revealed that cytosolic class I and II sHsp are developmentally expressed during all stages of pollen development. Different subsets of cytosolic sHsp genes are expressed in a stage-specific fashion suggesting that certain sHsp genes may play specific roles in early, others during later stages of pollen development. Heat stress results in a relatively weak and incomplete response in pollen: (i) the heat-induced levels of mRNA (excepting sHsp-2B, −3Cand -6) are much lower than in leaves, (ii) several sHsp are not detected after heat stress in pollen, although, they are heat-inducibly expressed in leaves. Application of heat stress, cold, and starvation, which induce microspore embryogenesis, modify mRNA levels and the patterns of 2-D-separated sHsp, but only heat stress enhances the expression of sHsp in microspores. There is no correlation of the expression of specific sHsp with the potential for microspore embryogenesis.Electronic supplementary material Electronic supplementary material is available for this article at and accessible for authorised users.     

Half-lives of messenger RNA species during growth and differentiation of Dictyostelium discoideum

The half-lives of functional messenger RNAs were determined by a method employing the drugs actinomycin D and daunomycin for the inhibition of mRNA synthesis; the activity of extracted mRNAs was determined by an in vitro translation assay. Several controls indicated that this method yielded reliable values for mRNA half-lives; in particular, the declining rate of protein synthesis in the presence of the drugs is due predominantly to the decay of translatable mRNA. This method was used to determine the half-lives of two specific mRNAs—encoding actin and a protein of MW 51,000—as well as that of total cytoplasmic mRNA activity during growth and at several times in differentiation. The half-lives of at least these two mRNAs were shown to be distinctly different from that of the total mRNA population—about 4 hr. However, no significant change in any of these half-lives was observed between growing and developing cells. Therefore wholesale alterations in the degradation rates of total and at least specific messages do not appear to play a role in the regulation of gene expression during Dictyostelium development.     

Analysis of the Complexity and Diversity of mRNAs from Pollen and Shoots of Tradescantia

The mRNAs of the mature pollen grain of Tradescantia paludosa at anesthesia and of vegetative shoots have been compared by analyzing the kinetics of hybridization between homologous and heterologous reactions of cDNA to poly(A)RNA in excess. The mRNAs in pollen can be divided into three abundance classes with complexities of 5.2 × 10⁴, 1.6 × 10⁶, and 2.1 × 10⁷ nucleotides. The three classes are made up of sequences that constitute 15, 60, and 24% of the mRNAs and each sequence is present on an average at 26,000, 3,400, and 100 copies, respectively, per pollen grain. About 20,000 different genes are expressed in pollen as compared to about 30,000 in vegetative shoots. Estimates have been made of pollen mRNA sequences shared with those of shoot tissue and of shoot sequences common to those in pollen.     

Functional nonequivalency of actin isovariants in Arabidopsis.

Plants encode at least two ancient and divergent classes of actin, reproductive and vegetative, and each class produces several subclasses of actin isovariants. To gain insight into the functional significance of the actin isovariants, we generated transgenic Arabidopsis lines that expressed a reproductive actin, ACT1, under the control of the regulatory sequences of a vegetative actin gene, ACT2. In the wild-type plants, ACT1 is predominantly expressed in the mature pollen, growing pollen tubes, and ovules, whereas ACT2 is constitutively and strongly expressed in all vegetative tissues and organs, but not in pollen. Misexpression of ACT1 in vegetative tissues causes dwarfing of plants and altered morphology of most organs, and the effects are in direct proportion to protein expression levels. Similar overexpression of ACT2 has little effect. Immunolocalization of actin in leaf cells from transgenic plants with highest levels of ACT1 protein revealed massive polymerization, bundling, and reorganization of actin filaments. This phenomenon suggests that misexpression of ACT1 isovariant in vegetative tissues affects the dynamics of actin and actin-associated proteins, in turn disrupting the organization of actin cytoskeleton and normal development of plants.     

Developmental changes in messenger RNAs and protein synthesis in Dictyostelium discoideum

The pattern of proteins synthesized at different stages of differentiation of the slime mold Dictyostelium discoideum was studied by two-dimensional polyacrylamide gel electrophoresis. Of the approximately 400 proteins detected during growth and/or development, synthesis of most continued throughout differentiation. Approximately 100 proteins show changes in their relative rates of synthesis. During the transition from growth to interphase, the major change observed is reduction in the relative rate of synthesis of about 8 proteins. Few further changes are noticeable until the stage of late cell aggregation, when production of about 40 new proteins begins and synthesis of about 10 is reduced considerably. Thereafter, there are few changes in the pattern of protein synthesis. Major changes in the relative rates of synthesis of a number of proteins are found during culmination, but few culmination-specific proteins are observed. In an attempt to understand the molecular basis for these changes, mRNA was isolated from different stages of differentiation and translated in an improved wheat germ cell-free system; the products were resolved on two-dimensional gels. The ratio of total translatable mRNA to total cellular RNA is constant throughout growth and differentiation. Messenger RNAs for many, but not all, developmentally regulated proteins can be identified by translation in cell-free systems. Actin is the major protein synthesized by vegetative cells and by early differentiating cells. The threefold increase in the relative rate of synthesis of actin during the first 2 hr of differentiation and the decrease which occurs thereafter can be accounted for by parallel changes in the amount of translatable actin mRNA. Most of the changes in the pattern of protein synthesis which occur during the late aggregation and culmination stages can also be accounted for by parallel increases or decreases in the amounts of translatable mRNAs encoding these proteins. It is concluded that mRNAs do not appear in a translatable form before synthesis of the homologous protein begins, and that regulation of protein synthesis during development is primarily at the levels of production or destruction of mRNA.     

Gene expression in rat brain

191 randomly selected cDNA clones prepared from rat brain cytoplasmic poly (A)+ RNA were screened by Northern blot hybridization to rat brain, liver and kidney RNA to determine the tissue distribution, abundance and size of the corresponding brain mRNA. 18% hybridized to mRNAs each present equally in the three tissues, 26% to mRNAs differentially expressed in the tissues, and 30% to mRNAs present only in the brain. An additional 26% of the clones failed to detect mRNA in the three tissues at an abundance level of about 0.01%, but did contain rat cDNA as demonstrated by Southern blotting; this class probably represents rare mRNAs expressed in only some brain cells. Therefore, most mRNA expressed in brain is either specific to brain or otherwise displays regulation. Rarer mRNA species tend to be larger than the more abundant species, and tend to be brain specific; the rarest, specific mRNAs average 5000 nucleotides in length. Ten percent of the clones hybridize to multiple mRNAs, some of which are expressed from small multigenic families. From these data we estimate that there are probably at most 30,000 distinct mRNA species expressed in the rat brain, the majority of which are uniquely expressed in the brain.     

Identification of Embryoid-Abundant Genes That Are Temporally Expressed during Pollen Embryogenesis in Wheat Anther Cultures

Uninucleate microspores in anther cultures of bread wheat (Triticum aestivum cv Pavon) are capable of producing haploid pollen embryoids and plants. To gain an understanding of this alternate pathway of pollen development, we constructed a cDNA library to young pollen embryoids, isolated embryoid-specific genes, and analyzed their expression patterns during morphogenesis. Two embryoid-abundant clones, pEMB4 and 94, were expressed very early during culture, suggesting that these genes are associated with development and are not simply expressed as a consequence of differentiation. The accumulation patterns of five cloned mRNAs may indicate the activation of specific genes associated with the major morphological and physiological activities connected with the differentiation of embryoids in vitro. These results suggest that embryoid-abundant gene expression is causally related to this pathway because gene expression is spatially and temporally specific and is not observed when microspores are cultured under noninductive conditions.     

The late pollen-specific actins in angiosperms

The actin gene family of Arabidopsis has eight functional genes that are grouped into two ancient classes, vegetative and reproductive, and into five subclasses based on their phylogeny and mRNA expression patterns. Progress in deciphering the functional significance of this diversity is hindered by the lack of tools that can distinguish the highly conserved subclasses of actin proteins at the biochemical and cellular level. In order to address the functional diversity of actin isovariants, we have used Arabidopsis recombinant actins as immunogens and produced several new anti-actin monoclonal antibodies. One of them, MAb45a, specifically recognizes two closely related reproductive subclasses of actins. On immunoblots, MAb45a reacts strongly with actins expressed in mature pollen but not with actins in other Arabidopsis tissues. Moreover, immunocytochemical studies show that this antibody can distinguish actin filaments in pollen tubes from those in most vegetative tissues. Peptide competition analyses demonstrate that asparagine at position 79 (Asn79) within an otherwise conserved sequence is essential for MAb45a specificity. Actins with the Asn79 epitope are also expressed in the mature pollen from diverse angiosperms and Ephedra but not from lower gymnosperms, suggesting that this epitope arose in an ancestor common to angiosperms and advanced gymnosperms more than 220 million years ago. During late pollen development in angio- sperms there is a switch in expression of actins from vegetative to predominantly reproductive subclasses, perhaps to fulfil the unique functions of pollen in fertilization.     

The mRNA–miRNA–lncRNA Regulatory Network and Factors Associated with Prognosis Prediction of Hepatocellular Carcinoma

The aim of this study was to identify novel prognostic mRNA and microRNA (miRNA) biomarkers for hepatocellular carcinoma (HCC) using methods in systems biology. Differentially expressed mRNAs, miRNAs, and long non-coding RNAs (lncRNAs) were compared between HCC tumor tissues and normal liver tissues in The Cancer Genome Atlas (TCGA) database. Subsequently, a prognosis-associated mRNA co-expression network, an mRNA–miRNA regulatory network, and an mRNA–miRNA–lncRNA regulatory network were constructed to identify prognostic biomarkers for HCC through Cox survival analysis. Seven prognosis-associated mRNA co-expression modules were obtained by analyzing these differentially expressed mRNAs. An expression module including 120 mRNAs was significantly correlated with HCC patient survival. Combined with patient survival data, several mRNAs and miRNAs, including CHST4, SLC22A8, STC2, hsa-miR-326, and hsa-miR-21 were identified from the network to predict HCC patient prognosis. Clinical significance was investigated using tissue microarray analysis of samples from 258 patients with HCC. Functional annotation of hsa-miR-326 and hsa-miR-21-5p indicated specific associations with several cancer-related pathways. The present study provides a bioinformatics method for biomarker screening, leading to the identification of an integrated mRNA–miRNA–lncRNA regulatory network and their co-expression patterns in relation to predicting HCC patient survival.     

Heat Shock Causes Selective Destabilization of Secretory Protein mRNAs in Barley Aleurone Cells

The aleurone layer of GA₃-stimulated barley (Hordeum vulgare L., cv Himalaya) grains is normally devoted to the synthesis and secretion of hydrolytic enzymes. Heat shock, however, suppresses the synthesis of the main hydrolytic enzyme, α-amylase, by destabilizing its otherwise highly stable mRNA (FC Belanger, MR Brodl, T-hD Ho [1986] Proc Natl Acad Sci USA 83: 1354-1358). In this paper we document that heat shock causes the suppression of the synthesis of some normal cellular proteins, while the synthesis of other normal cellular proteins is unaffected by heat shock. There are two major isozymic forms of α-amylase encoded by distinct mRNAs. The mRNA levels for both isozymic forms and the mRNA levels of two other secretory proteins, a protease and an endochitinase, were markedly reduced during heat shock. However, the levels of actin and β-tubulin mRNAs, both nonsecretory proteins, were not diminished during heat shock. In addition, the levels of three other mRNA species detected by a set of unidentified cDNA clones (the sequence of one shows that it lacks a signal sequence) remained unchanged during heat shock. These data indicate that there are two classes of normal cellular protein mRNAs with regard to the effect of heat shock upon their persistence in the cell, and suggest that the distinction between them is whether or not they encode secretory proteins.