Living organisms alter their gene-expression patterns to withstand stressful conditions. Drought, salinity, heat and chilling are potent abiotic stresses causing an alteration in gene expression. Among these, high temperature stress stimulates Heat Shock Transcription Factors (HSF) which activate heat shock promoters, thus turning on the heat shock genes. Heat shock proteins are, therefore, products of heat shock genes and are classified as per their molecular weight, including small heat shock proteins (sHsps). Hsps are chaperones playing an important role in stress tolerance. These consist of a conserved domain, flanked by N- and C-terminal regions termed the alphacrystallin domain (ACD), and are widely distributed in living beings. Their role as chaperones is to help the other proteins in protein-folding and prevent irreversible protein aggregation. The conserved domains in sHsps are essential for heat-stress tolerance and for their molecular chaperone activity, enabling plant survival under increasing temperatures, leading to adaptations needed for coping with extremes climatic conditions. The present study focusses on identification of ACDs in the whole-genome of&nbsp;Solanum lycopersicum. A multinational consortium, International Tomato Annotation Group (ITAG), funded in part by the EU-SOL Project, provides annotation of the whole genome of&nbsp;S. lycopersicumavailable in the public domain. We used several&nbsp;in silico&nbsp;methods for exploring alpha-crystallin domains in all the chromosomes of&nbsp;S. lycopersicum. Surprisingly, these ACDs were found to be present in all the chromosomes excepting Chromosome 4; these are highly conserved in sHsps and are related to heat tolerance

Mondal, Papiya

Prakash, M K Chandra

Thomas, Reena Rosy

English

Journal of Horticultural Sciences

INTRODUCTIONAlpha-crystallin domain (ACD) belongs to the classof small heat-shock proteins (sHsps) functioning as amolecular chaperone, preventing undesired protein-proteininteractions and assisting in refolding of denatured proteins(Liberek et al, 2008). The term ‘molecular chaperone’ isnormally used for describing the function of alpha-HSPs,as, these bind to and stabilize misfolded conformers ofproteins, and, facilitate refolding of proteins in vivo (Parselland Lindquist, 1993). To protect irreversible disaggregationof proteins, the chaperone activity of alpha-sHsps is limitedto binding unstable intermediates (Jorg and Elizabeth  1994).Most ACDs have some common structural and functionalfeatures, including the molecular chaperone activity. Alpha-crystallins merge into a highly synergistic and adaptablemulti-chaperone network to secure protein-quality controlin the cell (Franz, 2002). Productive delivery and refoldingIn silico analysis of whole-genome of Solanum lycopersicum for alpha-crystallindomains associated with heat stress toleranceM.K. Chandra Prakash, Reena Rosy Thomas and Papiya MondalSection of Economics & StatisticsICAR-Indian Institute of Horticultural Research Hessaraghatta Lake Post, Bengaluru - 560089, IndiaE-mail: mk_chandraprakash@yahoo.comABSTRACTLiving organisms alter their gene-expression patterns to withstand stressful conditions. Drought, salinity, heatand chilling are potent abiotic stresses causing an alteration in gene expression. Among these, high temperaturestress stimulates Heat Shock Transcription Factors (HSF) which activate heat shock promoters, thus turning on theheat shock genes. Heat shock proteins are, therefore, products of heat shock genes and are classified as per theirmolecular weight, including small heat shock proteins (sHsps). Hsps are chaperones playing an important role instress tolerance. These consist of a conserved domain, flanked by N- and C-terminal regions termed the alpha-crystallin domain (ACD), and are widely distributed in living beings. Their role as chaperones is to help the otherproteins in protein-folding and prevent irreversible protein aggregation. The conserved domains in sHsps are essentialfor heat-stress tolerance and for their molecular chaperone activity, enabling plant survival under increasingtemperatures, leading to adaptations needed for coping with extremes climatic conditions. The present study focusseson identification of ACDs in the whole-genome of Solanum lycopersicum. A multinational consortium, InternationalTomato Annotation Group (ITAG), funded in part by the EU-SOL Project, provides annotation of the whole genome of S.lycopersicum available in the public domain. We used several in silico methods for exploring alpha-crystallin domainsin all the chromosomes of S. lycopersicum. Surprisingly, these ACDs were found to be present in all the chromosomesexcepting Chromosome 4; these are highly conserved in sHsps and are related to heat tolerance.Key words: Solanum lycopersicum, alpha-crystallin domain (ACD), small heat shock proteins (sHsps), in silico, heatstressJ. Hortl. Sci.Vol. 10(2):143-146, 2015of misfolded proteins into their native state demands closecooperation with other cellular chaperones. Further, alpha-Hsps have a significant role in stabilizing the cell membrane.ACDs are conserved regions found in sHsps of allthe three domain of life (bacteria, archaea and eukarya),suggesting their wide importance. There are different classesof ACD proteins comprising classical sHsps and, likely,chaperones. The α-crystallin domains are fundamentalbuilding blocks for most sHsps, consisting of several betastrands accountable for dimer formation arranged into twobeta-sheets (Tariq et al, 2010). Mostly, varying the sHspsacquires less conserved N- and C-terminal extensions,whereas, greater sequence similarities can be seen inconserved ACDs (Eisenhardt, 2013). Unfortunately, verylittle information is available on ACDs. However, someexamples indicate that this family is of great significance.Recently, in Arabidopsis, one ACD protein was reported144to be an essential element of a specific resistance-mechanism against systemic spreading of the tobacco etchvirus (Whitham et al, 2000). It was reported that both sHspsand α-crystallins show ATP-independent molecularchaperone activity and, under heat stress, interact withpartially unfolded polypeptides to prevent unspecificaggregation of protein substrates (Jakob et al, 1993 andTyedmers et al, 2010).The tomato genome: Tomato Genome Consortium startedits work in the year 2003. Genome of the tomato (Solanumlycopersicum L.) was sequenced completely and publishedin 2012 (ftp://ftp.sgn.cornell.edu/genomes/Solanum_lycopersicum/annotation/). Size of the tomatogenome is 950 megabases (Mb), divided into 12 linearmolecules, each containing different chromosomes. Theshortest is Chromosome 6, with 46,041,647 nucleotides; thelongest is Chromosome 1, with 90,304,255 nucleotides.Average length of the chromosome is 65 million nucleotidesof DNA sequence. In the present study, ACDs available inwhole-genome of S. lycopersicum have been explored.In computational biology, genes can be detected bycomparing genomes of related species. These detectevolutionary pressure for conservation, especiallyidentification of conserved regions (including markers) as,these are conserved evolutionarily across species, andinclude solanaceous crops (Reena et al, 2013).Conservedness relies heavily on sequence-similarity, whoserun-time grows with square of the number and length of thealigned sequence, demanding noteworthy computationalresources (Nagar and Hahsler 2013).MATERIAL AND METHODSIdentification of conserved domains in genes is oneof the important steps in understanding the genome of anyspecies. Sequence-similarities provide evidence forfunctional and structural conservation, alongwith evolutionary relationships, between sequences.Specifically, sHsp sequences are highly conserved acrossspecies, despite evolutionary pressure (Chandraprakash etal, 2013). Comparative analysis is a key method by whichfunctional elements are identified. Ligand-binding sites ofproteins and active sites of enzymes are the most highlyconserved protein sequences. To identify conservedelements in a desired gene, the same sequence from severalspecies should be aligned and common areas should beidentified.In our work, several in silico methods were used forshowing the presence of conserved domains, especiallyACDs belonging to sHsp of S. lycopersicum. PublishedsHsp sequences were used for comparative analysis toidentify similar regions in the whole-genome of S.lycopersicum. The identified, similar regions in tomatogenomic sequences were obtained. These sequences wereuploaded onto NCBI batch CD search program in anappropriate format to be processed as batch files. NCBIbatch CD search program is one of the programs used forsearching the input sequences against Conserved DomainDatabase (CDD). The output generated (CDD) is a tab-delimited list of conserved-domain hits, found on eachprotein, against input query sequences of S. lycopersicum.From the output file, matching sequences of α-crystallindomain were clustered chromosome-wise. These ACDswere found to be highly conserved and available in almostall the chromosomes in multiple copies.RESULTS AND DISCUSSIONGenerally, highly-conserved proteins are needed infundamental cellular functions, stability or reproduction.Conservation of the protein structure is indicated bypresence of functionally equivalent amino acid residues (notnecessarily identical) and structures between analogousparts of the protein structure. Chandraprakash et al (2013)reported HSPs to be evolutionarily conserved in solanaceouscrops. Defined by conserved alpha- crystalline domains, asequence of 90 amino acid residues (approximately)constitutes small heat shock proteins (also known as α-Hsps) (MacRae, 2000). Most multiple α-Hsps translated inplants are housed in different cellular compartments, toprevent them from interacting with each other (Franz, 2002).However, engineering a single transcribed gene is not ofmuch use, as, more than one stress-responsive genes maybe necessary for survival of a plant under extremeconditions. At the genomic level, understanding theexpression of a specific protein under a particular abioticstress can provide a base for recognizing genes (Reena etal, 2013). Expression of sHsps is seen in response to variouskinds of abiotic stresses, including extreme temperatures,oxidative stress, osmotic stress, etc.In the present study, published sequences matchedagainst the available S. lycopersicum database revealed61 Alpha-crystallin domains to be widely distributedthroughout the whole-genome of S. lycopersicum, exceptin Chromosome 4. A genome-wide analysis for presence ofACDs revealed these to be conserved in sHsps. Achromosome-wise distribution of ACDs in the whole-genomeof S. lycopersicum is shown in Fig. 1.Chandra Prakash et alJ. Hortl. Sci.Vol. 10(2):143-146, 2015145In silico analysis in wheat had shown the presenceof alpha crystalline domain (Kumar et al, 2012). In thehuman genome, α-crystallin–related small heat shockproteins are dispersed over nine chromosomes (Kappé etal, 2003). Chromosome-wise distribution of alpha crystallindomains (ACDs) in S. lycopersicum, along with the natureof protein and matching similarity-values, is presented inTable 1.Genome-wide, this ACD is sited maximally inChromosomes 2 and 9, followed by Chromosomes 12, 8, 7,6, 11, 3, 1, 10 and 5, with the exception of Chromosome 4.ACDs in Chromosome 6 had maximum matching similarity.Genome-wide analysis of ACDs revealed these genes tobe enriched on several chromosomes, majorly, 15% inChromosomes 2 and 9.ACDs are unusually abundant and cover a segmentin heat stress induced proteins termed small heat shockproteins, ranging in size from ~ 17 to 30 kDa. These arehighly conserved sequences of around 90 amino acids, foundextensively in all the domains of life. Representation of atypical ACD structure with two conserved regions that forma sandwich of two β pleated-sheets is shown in Fig. 2. Theubiquitous nature of ACDs implies that these domains areof great significance and help plants combat heat-stress andrender longevity.ACKNOWLEDGEMENTThe authors wish to thank Centre for AgriculturalBioinformatics, and, PI of CAB-IN project for funding thiswork. They are also thankful to ICAR-Indian Institute ofHorticultural Research and IASRI, for technical support.REFERENCESChandraprakash, M.K., Reena Rosy Thomas, KrishnaReddy, M. and Sukhada Mohandas. 2013.Molecularevolutionary conservedness of small heat shockprotein sequences in Solanaceae crops using in silicomethods. J. Hortl. Sci., 8:82-87Eisenhardt, B.D. 2013. Small heat shock proteins: recentdevelopments. Biomol. Concepts,4:583-595Franz Narberhaus. 2002. Alpha-crystallin-type heat shockproteins: socializing minichaperones in the context ofa multichaperone network. Microbiol. Mol. Biol.Rev., 66:64-93Jakob, U., Gaestel, M., Engel, K. and Buchner, J. 1993.Small heat shock proteins are molecular chaperones.J. Biol. Chem., 268:1517-20Jorg Becker and Elizabeth A. Craig. 1994. Heat-shockproteins as molecular chaperones. European J.Biochem., 219:11-23Kappé, G., Franck, E., Verschuure, P., Boelens, W.C.,Leunissen, J.A.M. and de Jong, W.W. 2003. Thehuman genome encodes 10 α-crystallin-related smallheat shock proteins: HspB1-10. Cell StressChaperones, 8:53-61Kumar, R.R., Singh, G.P., Sharma, S.K., Singh, K., Goswami,S. and Rai, R.D. 2012. Molecular cloning of HSP17gene (sHSP) and their differential expression underexogenous putrescine and heat shock in wheatFig. 1. Distribution of Alpha-crystallin domains (ACD) in Solanumlycopersicum chromosomesTable 1. Distribution of α-crystalline domains (ACD) in the whole-genome of Solanum lycopersicumSl. Chromosome Total number Nature of Hit-valueNo. No. of ACDs protein range1 CHR 1 3 sHSP 599-7342 CHR 2 9 sHSP 523-9593 CHR 3 4 sHSP 649-7654 CHR 4 - - -5 CHR 5 2 sHSP 507-10336 CHR 6 5 sHSP 667-88247 CHR 7 6 sHSP 597-11018 CHR 8 7 sHSP 791-9489 CHR 9 9 sHSP 616-100710 CHR 10 3 sHSP 520-78011 CHR 11 5 sHSP 595-93312 CHR 12 8 sHSP 625-941Fig. 2. Quaternary structure of a typical ACDIn silico analysis of whole-genome of tomato for heat stressJ. Hortl. Sci.Vol. 10(2):143-146, 2015146(Triticum aestivum). African J. Biotech., 11:16800-16808Liberek, K., Lewandowska, A. and Zietkiewicz, S. 2008.Chaperones in control of protein disaggregation.EMBO J., 27:328-335MacRae, T.H. 2000. Structure and function of small heatshock/alpha-crystallin proteins: established conceptsand emerging ideas. Cell Mol. Life Sci., 57:899-913Nagar, A. and Hahsler, M. 2013. Fast discovery andvisualization of conserved regions in DNA sequencesusing quasi-alignment. BMC Bioinformatics, 14Suppl., 11:S2Parsell, D.A. and Lindquist, S. 1993. The function of heatshock proteins in stress tolerance: degradation andreactivation of damaged proteins. Annu. Rev. Genet.,27:437-497Reena Rosy Thomas, Chandraprakash, M.K., Krishna(MS Received 31 March 2015, Revised 15 November 2015, Accepted 18 November 2015)Reddy, M., Sukhada Mohandas and Riaz Mahmood.2013. Microsatellite identification in Solanaceae cropsassociated with Nucleoside Diphosphate Kinase(NDK) specific to abiotic stress tolerance through insilico analysis. J. Hortl. Sci., 8:195-198Tariq Mahmood, Waseem Safdar, Bilal Haider Abbasi andSaqlan Naqvi, S.M. 2010. An overview on the smallheat shock proteins. African J. Biotech., 9:927-939Tyedmers, J., Mogk, A. and Bukau, B. 2010. Cellularstrategies for controlling protein aggregation. Nat’l.Rev. Mol. Cell Biol., 11:777-788Whitham, S.A., Anderberg, R.J., Chrisholm, S.T. andCarrington, J.C. 2000. Arabidopsis RTM2 gene isnecessary for specific restriction of Tobacco EtchVirus and encodes an unusual small heat shock likeprotein. Pl. Cell, 12:569-582Chandra Prakash et alJ. Hortl. Sci.Vol. 10(2):143-146, 2015

In silico Analysis of whole-Genome of Solanum lycopersicum for Alpha-Crystallin Domains Associated with Heat Stress Tolerance

Living organisms alter their gene-expression patterns to withstand stressful conditions. Drought, salinity, heat and chilling are potent abiotic stresses causing an alteration in gene expression. Among these, high temperature stress stimulates Heat Shock Transcription Factors (HSF) which activate heat shock promoters, thus turning on the heat shock genes. Heat shock proteins are, therefore, products of heat shock genes and are classified as per their molecular weight, including small heat shock proteins (sHsps). Hsps are chaperones playing an important role in stress tolerance. These consist of a conserved domain, flanked by N- and C-terminal regions termed the alphacrystallin domain (ACD), and are widely distributed in living beings. Their role as chaperones is to help the other proteins in protein-folding and prevent irreversible protein aggregation. The conserved domains in sHsps are essential for heat-stress tolerance and for their molecular chaperone activity, enabling plant survival under increasing temperatures, leading to adaptations needed for coping with extremes climatic conditions. The present study focusses on identification of ACDs in the whole-genome of Solanum lycopersicum. A multinational consortium, International Tomato Annotation Group (ITAG), funded in part by the EU-SOL Project, provides annotation of the whole genome of S. lycopersicumavailable in the public domain. We used several in silico methods for exploring alpha-crystallin domains in all the chromosomes of S. lycopersicum. Surprisingly, these ACDs were found to be present in all the chromosomes excepting Chromosome 4; these are highly conserved in sHsps and are related to heat tolerance

In silico Analysis of whole-Genome of Solanum lycopersicum for Alpha-Crystallin Domains Associated with Heat Stress Tolerance

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