Reduced physiological plasticity in a fish adapted to stable temperatures

Publisher Copyright: Copyright © 2022 the Author(s).Plasticity can allow organisms to maintain consistent performance across a wide range of environmental conditions. However, it remains largely unknown how costly plasticity is and whether a trade-off exists between plasticity and performance under optimal conditions. Biological rates generally increase with temperature, and to counter that effect, fish use physiological plasticity to adjust their biochemical and physiological functions. Zebrafish in the wild encounter large daily and seasonal temperature fluctuations, suggesting they should display high physiological plasticity. Conversely, laboratory zebrafish have been at optimal temperatures with low thermal fluctuations for over 150 generations. We treated this domestication as an evolution experiment and asked whether this has reduced the physiological plasticity of laboratory fish compared to their wild counterparts. We measured a diverse range of phenotypic traits, from gene expression through physiology to behavior, in wild and laboratory zebrafish acclimated to 15 temperatures from 10 °C to 38 °C. We show that adaptation to the laboratory environment has had major effects on all levels of biology. Laboratory fish show reduced plasticity and are thus less able to counter the direct effects of temperature on key traits like metabolic rates and thermal tolerance, and this difference is detectable down to gene expression level. Rapid selection for faster growth in stable laboratory environments appears to have carried with it a trade-off against physiological plasticity in captive zebrafish compared with their wild counterparts.Peer reviewe

The IDA-LIKE peptides IDL6 and IDL7 are negative modulators of stress responses in Arabidopsis thaliana

Small signalling peptides have emerged as important cell to cell messengers in plant development and stress responses. However, only a few of the predicted peptides have been functionally characterized. Here, we present functional characterization of two members of the IDA-LIKE (IDL) peptide family in Arabidopsis thaliana, IDL6 and IDL7. Localization studies suggest that the peptides require a signal peptide and C-terminal processing to be correctly transported out of the cell. Both IDL6 and IDL7 appear to be unstable transcripts under post-transcriptional regulation. Treatment of plants with synthetic IDL6 and IDL7 peptides resulted in down-regulation of a broad range of stress-responsive genes, including early stress-responsive transcripts, dominated by a large group of ZINC FINGER PROTEIN (ZFP) genes, WRKY genes, and genes encoding calcium-dependent proteins. IDL7 expression was rapidly induced by hydrogen peroxide, and idl7 and idl6 idl7 double mutants displayed reduced cell death upon exposure to extracellular reactive oxygen species (ROS). Co-treatment of the bacterial elicitor flg22 with IDL7 peptide attenuated the rapid ROS burst induced by treatment with flg22 alone. Taken together, our results suggest that IDL7, and possibly IDL6, act as negative modulators of stress-induced ROS signalling in Arabidopsis.Peer reviewe

Arabidopsis thaliana MIRO1 and MIRO2 GTPases Are Unequally Redundant in Pollen Tube Growth and Fusion of Polar Nuclei during Female Gametogenesis

MIRO GTPases have evolved to regulate mitochondrial trafficking and morphology in eukaryotic organisms. A previous study showed that T-DNA insertion in the Arabidopsis MIRO1 gene is lethal during embryogenesis and affects pollen tube growth and mitochondrial morphology in pollen, whereas T-DNA insertion in MIRO2 does not affect plant development visibly. Phylogenetic analysis of MIRO from plants revealed that MIRO 1 and 2 orthologs in dicots cluster in two separate groups due to a gene/genome duplication event, suggesting that functional redundancy may exists between the two MIRO genes. To investigate this possibility, we generated miro1(+/−)/miro2-2(−/−) plants. Compared to miro1(+/−) plants, the miro1(+/−)/miro2-2(−/−) plants showed increased segregation distortion. miro1(+/−)/miro2-2(−/−) siliques contained less aborted seeds, but more than 3 times the number of undeveloped ovules. In addition, reciprocal crosses showed that co-transmission through the male gametes was nearly absent, whereas co-transmission through the female gametes was severely reduced in miro1(+/−)/miro2-2(−/−) plants. Further investigations revealed that loss of MIRO2 (miro2(−/−)) function in the miro1(+/−) background enhanced pollen tube growth defects. In developing miro1(+/−)/miro2(−/−) embryo sacs, fusion of polar nuclei was further delayed or impaired compared to miro1 plants. This phenotype has not been reported previously for miro1 plants and coincides with studies showing that defects in some mitochondria-targeted genes results in the same phenotype. Our observations show that loss of function in MIRO2 in a miro1(+/−) background enhances the miro1(+/−) phenotype significantly, even though miro2(−/−) plants alone does not display any phenotypes. Based on these findings, we conclude that MIRO1 and MIRO2 are unequally redundant and that a proportion of the miro1(+/−)/miro2(−/−) plants haploid gametes displays the complete null phenotype of MIRO GTPase function at key developmental stages

Genetic, molecular and functional studies of RAC GTPases and the WAVE-like regulatory protein complex in Arabidopsis thaliana.

Small GTP-binding proteins are molecular switches that serve as important regulators of numerous cellular processes. In animal and plant cells, the Rho family of small GTPases participate in e.g. organisation of the actin cytoskeleton, production of reactive oxygen species through the NADPH oxidase complex, regulation of gene expression. The three most extensively studied subgroups of the Rho GTPase family are Cdc42, Rho and Rac. One of the mechanisms by which animal Rac and Cdc42 GTPases regulate actin filament organisation is through activation of the ARP2/3 complex, a multimeric protein complex which induces branching and nucleation/elongation/polymerisation of actin filaments. Activation of the ARP2/3 complex by Rac and Cdc42 is mediated through the proteins WAVE and WASP, respectively. In a search for Ras-like GTPases in Arabidopsis, we identified a family of genes with similarity to Rac GTPases. Screens of cDNA and genomic libraries resulted in the finding of 11 genes named ARACs/AtRACs. Genes encoding Rho, Cdc42 or Ras homologues were not identified. Expression analysis of AtRAC1 to AtRAC5 indicated that AtRAC1, AtRAC3, AtRAC4 and AtRAC5 are expressed in all parts of the plant, whereas AtRAC2 is preferentially expressed in root, hypocotyl and stem. The AtRAC gene family can be divided into two main groups based on sequence similarity, gene structure and post-translational modification. AtRAC group II genes contain an additional exon, caused by the insertion of an intron which disrupts the C-terminal geranylgeranylation motif. Instead, group II AtRACs contain a putative motif for palmitoylation. Phylogenetic analyses indicated that the division of plant RACs into group I and group II occurred before the split of monocotyledonous and dicotyledonous plants. Analyses of the genes neighbouring AtRAC genes revealed that several of the plant RAC genes have been created through duplications. The restricted/tissue-specific expression pattern of AtRAC2 led us to do a more detailed expression analysis of this gene. A 1.3 kb fragment of the upstream (regulatory) sequence of AtRAC2 directed expression of GUS or GFP to developing primary xylem in root, hypocotyl, leaves and stem. In root tips, the onset GUS staining or GFP fluorescence regulated by the AtRAC2 promoter slighty preceded the appearance of secondary cell walls. In stems, GUS staining coincided with thickening of xylem cell walls. Transgenic plants expressing constitutively active AtRAC2 displayed defects in the polar growth of leaf epidermal cells, indicating that AtRAC2 may be able to regulate the actin cytoskeleton. Surprisingly, an AtRAC2 T-DNA insertion mutant did not show any observable phenotypes. GFP fusion proteins of wild type and constitutively active AtRAC2 were both localised to the plasma membrane. The data suggest that AtRAC2 is involved in development of xylem vessels, likely through regulation of the actin cytoskeleton or NADPH oxidase. The role of RAC GTPases in regulation of the actin cytoskeleton in plants is well documented. However, although the ARP2/3 complex had been identified in plants/Arabidopsis, the mechanisms regulating this complex were unknown. Through database searches, we identified three Arabidopsis genes, AtBRK1, AtNAP and AtPIR, which encoded proteins with similarity to subunits of a protein complex shown to regulate the activity of WAVE1 in mammalian cells. T-DNA inactivation mutants of AtNAP and AtPIR displayed morphological defects on epidermal cells undergoing polar expansion, such as trichomes and leaf pavement cells. The phenotypes were similar to those observed for ARP2/3 complex mutants, suggesting that AtNAP and AtPIR act in the same pathway as the ARP2/3 complex in plants. The actin cytoskeleton in atnap and atpir mutants was less branched than in wild type plants; instead, actin filaments aggregated in thick actin bundles. Finally, we have recently discovered a small gene family encoding putative WAVE homologues. In mammalian cells, Rac activates WAVE1 through binding to PIR121 or Sra1 (the mammalian homologues of AtPIR). The discovery of a putative WAVE regulatory complex as well as putative WAVE homologues in Arabidopsis suggests that plant RAC GTPases regulate organisation of the actin cytoskeleton during polar growth at least partly through the ARP2/3 complex, using an evolutionarily conserved mechanism

Dynamic responses to silicon in Thalassiosira pseudonana - Identification, characterisation and classification of signature genes and their corresponding protein motifs

The diatom cell wall, or frustule, is a highly complex, three-dimensional structure consisting of nanopatterned silica as well as proteins and other organic components. While some key components have been identified, knowledge on frustule biosynthesis is still fragmented. The model diatom Thalassiosira pseudonana was subjected to silicon (Si) shift-up and shift-down situations. Cellular and molecular signatures, dynamic changes and co-regulated clusters representing the hallmarks of cellular and molecular responses to changing Si availabilities were characterised. Ten new proteins with silaffin-like motifs, two kinases and a novel family of putatively frustule-associated transmembrane proteins induced by Si shift-up with a possible role in frustule biosynthesis were identified. A separate cluster analysis performed on all significantly regulated silaffin-like proteins (SFLPs), as well as silaffin-like motifs, resulted in the classification of silaffins, cingulins and SFLPs into distinct clusters. A majority of the genes in the Si-responsive clusters are highly divergent, but positive selection does not seem to be the driver behind this variability. This study provides a high-resolution map over transcriptional responses to changes in Si availability in T. pseudonana. Hallmark Si-responsive genes are identified, characteristic motifs and domains are classified, and taxonomic and evolutionary implications outlined and discussed.publishedVersio

The effects of phosphorus limitation on carbon metabolism in diatoms

Phosphorus is an essential element for life, serving as an integral component of nucleic acids, lipids and a diverse range of other metabolites. Concentrations of bioavailable phosphorus are low in many aquatic environments. Microalgae, including diatoms, apply physiological and molecular strategies such as phosphorus scavenging or recycling as well as adjusting cell growth in order to adapt to limiting phosphorus concentrations. Such strategies also involve adjustments of the carbon metabolism. Here, we review the effect of phosphorus limitation on carbon metabolism in diatoms. Two transcriptome studies are analysed in detail, supplemented by other transcriptome, proteome and metabolite data, to gain overview of different pathways and their responses. Phosphorus, nitrogen and silicon limitation responses are compared, and similarities and differences discussed. We use the current knowledge to propose a suggestive model for the carbon flow in phosphorus replete and phosphorus-limited diatom cells

NAPP and PIRP Encode Subunits of a Putative Wave Regulatory Protein Complex Involved in Plant Cell Morphogenesis

The ARP2/3 complex is an important regulator of actin nucleation and branching in eukaryotic organisms. All seven subunits of the ARP2/3 complex have been identified in Arabidopsis thaliana, and mutation of at least three of the subunits results in defects in epidermal cell expansion, including distorted trichomes. However, the mechanisms regulating the activity of the ARP2/3 complex in plants are largely unknown. In mammalian cells, WAVE and WASP proteins are involved in activation of the ARP2/3 complex. WAVE1 activity is regulated by a protein complex containing NAP1/HEM/KETTE/GEX-3 and PIR121/Sra-1/CYFIP/GEX-2. Here, we show that the WAVE1 regulatory protein complex is partly conserved in plants. We have identified Arabidopsis genes encoding homologs of NAP1 (NAPP), PIR121 (PIRP), and HSPC300 (BRK1). T-DNA inactivation of NAPP and PIRP results in distorted trichomes, similar to ARP2/3 complex mutants. The napp-1 mutant is allelic to the distorted mutant gnarled. The actin cytoskeleton in napp-1 and pirp-1 mutants shows orientation defects and increased bundling compared with wild-type plants. The results presented show that activity of the ARP2/3 complex in plants is regulated through an evolutionarily conserved mechanism

Whole-cell response to nitrogen depletion in the diatom Phaeodactylum tricornutum

Algal growth is strongly affected by nitrogen (N) availability. Diatoms, an ecologically important group of unicellular algae, have evolved several acclimation mechanisms to cope with N deprivation. In this study, we integrated physiological data with transcriptional and metabolite data to reveal molecular and metabolic modifications in N-deprived conditions in the marine diatom Phaeodactylum tricornutum. Physiological and metabolite measurements indicated that the photosynthetic capacity and chlorophyll content of the cells decreased, while neutral lipids increased in N-deprived cultures. Global gene expression analysis showed that P. tricornutum responded to N deprivation through an increase in N transport, assimilation, and utilization of organic N resources. Following N deprivation, reduced biosynthesis and increased recycling of N compounds like amino acids, proteins, and nucleic acids was observed at the transcript level. The majority of the genes associated with photosynthesis and chlorophyll biosynthesis were also repressed. Carbon metabolism was restructured through downregulation of the Calvin cycle and chrysolaminarin biosynthesis, and co-ordinated upregulation of glycolysis, the tricarboxylic acid cycle, and pyruvate metabolism, leading to funnelling of carbon sources to lipid metabolism. Finally, reallocation of membrane lipids and induction of de novo triacylglycerol biosynthesis directed cells to accumulation of neutral lipids.© The Author 2015. Published by Oxford University Press on behalf of the Society for Experimental Biology. This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/3.0/), which permits unrestricted reuse, distribution, and reproduction in any medium, provided the original work is properly cited