Plant-specific histone deacetylases associate with ARGONAUTE4 to promote heterochromatin stabilization and plant heat tolerance

High temperature causes devasting effects on many aspects of plant cells and thus enhancing plant heat tolerance is critical for crop production. Emerging studies have revealed the important roles of chromatin modifications in heat stress responses. However, how chromatin is regulated during heat stress remains unclear. We show that heat stress results in heterochromatin disruption coupled with histone hyperacetylation and DNA hypomethylation. Two plant-specific histone deacetylases HD2B and HD2C could promote DNA methylation and relieve the heat-induced heterochromatin decondensation. We noted that most DNA methylation regulated by HD2B and HD2C is lost upon heat stress. HD2B- and HD2C-regulated histone acetylation and DNA methylation are dispensable for heterochromatin maintenance under normal conditions, but critical for heterochromatin stabilization under heat stress. We further showed that HD2B and HD2C promoted DNA methylation through associating with ARGONAUTE4 in nucleoli and Cajal bodies, and facilitating its nuclear accumulation. Thus, HD2B and HD2C act both canonically and noncanonically to stabilize heterochromatin under heat stress. This study not only reveals a novel plant-specific crosstalk between histone deacetylases and key factor of DNA methylation pathway, but also uncovers their new roles in chromatic regulation of plant heat tolerance.

Identification of differentially expressed genes under heat stress conditions in rice (Oryza sativa L.)

Rice production in recent years is highly affected by rapidly increasing temperatures in the tropical and sub-tropical countries, which threatens the sustainable production in near future. Hence, understanding the heat tolerance mechanism and evolving tolerant varieties is an immense need in the staple crop rice. An experiment has been conducted to identify differentially expressed genes in rice under heat stress conditions by employing a diverse set of 32 rice genotypes that includes reported heat tolerant genotypes Nagina 22 (N22) and Dular. Screening of the genotypes at field conditions during Summer-2018 for reproductive stage heat tolerance (wherein the mean minimum (29.8 °C) and maximum (38.4 °C) temperatures surpassed optimum temperatures (25 °C night/30 °C day) required for rice flowering and grain filling stages) and lab conditions employing thermal induction response (TIR) technique to know the genotype's acquired thermal tolerance revealed that the genotype FR13A (indica landrace) showed highest overall performance for multitude of traits viz., 95.29% of spikelet fertility (SF-%) at field level and 100% seedling survival percentage (SSP) at sub-lethal temperatures under laboratory conditions. The relative performance (under TIR) across all the three traits viz., relative shoot length (RSL) (4.91), relative root length (RRL) (equal to the control) and relative seedling dry weight (RSDW) (6.94) over control is high when compared to the other genotypes under study. However, the highly susceptible genotype PUSA1121 performed with 43.59 of SF%, 73.33% SSP, - 43.59 of RSL, - 36.02 of RRL over control. Hence, these contrasting genotypes were used for molecular analysis for identification of differentially expressed genes by employing 29 heat related gene specific primers. Five genes viz., OsGSK1, TT1, HSP70-OsEnS-45, OsHSP74.8 and OsHSP70 have shown differential expression between the two genotypes. Hence, the genotype FR13A, an 'indica' genotype, can be utilized in heat tolerance breeding programmes as donor parent in addition to the reported 'aus' genotypes, N22 and Dular. To our knowledge this is the first indica genotype identified for heat tolerance. The HSP70s, TT1 and OsGSK1 that proved with differential expression might be used for identification of gene specific InDels and thereby to develop functional markers that help in the marker assisted introgression breeding to develop heat tolerant varieties that can sustain production under dramatically changing climatic conditions.

Genome-Wide Identification, Classification and Expression Analysis of the HSP Gene Superfamily in Tea Plant (Camellia sinensis)

Heat shock proteins (HSPs) function as molecular chaperones. These proteins are encoded by a multigene family whose members play crucial roles in plant growth, development and stress response. However, little is known about the HSP gene superfamily in tea plant. In this study, a total of 47 CsHSP genes were identified, including 7 CsHSP90, 18 CsHSP70, and 22 CssHSP genes. Phylogenetic and composition analyses showed that CsHSP proteins in the same subfamily have similar gene structures and conserved motifs, but significant differences exist in the different subfamilies. In addition, expression analysis revealed that almost all CsHSP genes were specifically expressed in one or more tissues, and significantly induced under heat and drought stress, implying that CsHSP genes play important roles in tea plant growth, development, and response to heat and drought stress. Furthermore, a potential interaction network dominated by CsHSPs, including HSP70/HSP90 organizing protein (HOP) and heat shock transcription factor (HSF), is closely related to the abovementioned processes. These results increase our understanding of CsHSP genes and their roles in tea plant, and thus, this study could contribute to the cloning and functional analysis of CsHSP genes and their encoded proteins in the future.

Transcriptome analysis reveals the role of nitric oxide in Pleurotus eryngii responses to Cd2+ stress

Pleurotus eryngii is widely cultivated in China. However, our understanding of its transcriptional response to heavy metal stress and the underlying mechanism of nitric oxide (NO) in enhancing its tolerance to heavy metals is limited. In the present study, RNA-seq was used to generate large transcript sequences from P. eryngii exposed to cadmium chloride (CdCl₂) and exogenous NO. A total of 45,833 unigenes were assembled from the P. eryngii transcriptome, of which 32,333 (70.54%) unigenes matched known proteins in the nr database. Transcriptional analysis revealed that putative genes encoding heat shock proteins (HSPs) and genes participating in glycerolipid metabolism and steroid biosynthesis were significantly up-regulated in P. eryngii exposed to 50 μM Cd (P < 0.05). P. eryngii mycelia exposed to extremely high levels of heavy metals showed an increase in biomass when exogenous NO was added to the culture. The collaboration of putative oxidoreductase, dehydrogenase, reductase, transferase genes and transcription factors such as "GTPase activator activity", "transcription factor complex", "ATP binding", "GTP binding", and "enzyme activator activity", which were significantly up-regulated in samples induced by exogenous NO, contributed to the enhancement of P. eryngii tolerance to extremely high levels of heavy metals. The study provides a new insight into the transcriptional response of P. eryngii to extremely high levels of heavy metals and the mechanism of NO in enhancing heavy metal tolerance.