Your search keyword '"Rajendra, T."' showing total 8 results

1. Gemin3Is an Essential Gene Required for Larval Motor Function and Pupation in Drosophila

Author

Shpargel, Karl B., Praveen, Kavita, Rajendra, T. K., and Matera, A. Gregory

Abstract

The assembly of metazoan Sm-class small nuclear ribonucleoproteins (snRNPs) is an elaborate, step-wise process that takes place in multiple subcellular compartments. The initial steps, including formation of the core RNP, are mediated by the survival motor neuron (SMN) protein complex. Loss-of-function mutations in human SMN1result in a neuromuscular disease called spinal muscular atrophy. The SMN complex is comprised of SMN and a number of tightly associated proteins, collectively called Gemins. In this report, we identify and characterize the fruitfly ortholog of the DEAD box protein, Gemin3. DrosophilaGemin3 (dGem3) colocalizes and interacts with dSMN in vitro and in vivo. RNA interference for dGem3 codepletes dSMN and inhibits efficient Sm core assembly in vitro. Transposon insertion mutations in Gemin3are larval lethals and also codeplete dSMN. Transgenic overexpression of dGem3 rescues lethality, but overexpression of dSMN does not, indicating that loss of dSMN is not the primary cause of death. Gemin3mutant larvae exhibit motor defects similar to previously characterized Smnalleles. Remarkably, appreciable numbers of Gemin3mutants (along with one previously undescribed Smnallele) survive as larvae for several weeks without pupating. Our results demonstrate the conservation of Gemin3 protein function in metazoan snRNP assembly and reveal that loss of either Smnor Gemin3can contribute to neuromuscular dysfunction.

Published

2009

2. Gemin3 Is an Essential Gene Required for Larval Motor Function and Pupation in Drosophila

Author

Shpargel, Karl B., Praveen, Kavita, Rajendra, T. K., and Matera, A. Gregory

Abstract

The assembly of metazoan Sm-class small nuclear ribonucleoproteins (snRNPs) is an elaborate, step-wise process that takes place in multiple subcellular compartments. The initial steps, including formation of the core RNP, are mediated by the survival motor neuron (SMN) protein complex. Loss-of-function mutations in human SMN1 result in a neuromuscular disease called spinal muscular atrophy. The SMN complex is comprised of SMN and a number of tightly associated proteins, collectively called Gemins. In this report, we identify and characterize the fruitfly ortholog of the DEAD box protein, Gemin3. Drosophila Gemin3 (dGem3) colocalizes and interacts with dSMN in vitro and in vivo. RNA interference for dGem3 codepletes dSMN and inhibits efficient Sm core assembly in vitro. Transposon insertion mutations in Gemin3 are larval lethals and also codeplete dSMN. Transgenic overexpression of dGem3 rescues lethality, but overexpression of dSMN does not, indicating that loss of dSMN is not the primary cause of death. Gemin3 mutant larvae exhibit motor defects similar to previously characterized Smn alleles. Remarkably, appreciable numbers of Gemin3 mutants (along with one previously undescribed Smn allele) survive as larvae for several weeks without pupating. Our results demonstrate the conservation of Gemin3 protein function in metazoan snRNP assembly and reveal that loss of either Smn or Gemin3 can contribute to neuromuscular dysfunction.

Published

2009

3. Male sterility associated with overexpression of the noncodinghsrΩgene in cyst cells of testis ofDrosophila melanogaster

Author

Rajendra, T. K., Prasanth, K. V., and Lakhotia, S. C.

Abstract

Of the several noncoding transcripts produced by thehsrΩgene ofDrosophila melanogaster, the nucleus-limited >10-kb hsrΩ-n transcript colocalizes with heterogeneous nuclear RNA binding proteins (hnRNPs) to form fine nucleoplasmic omega speckles. Our earlier studies suggested that the noncoding hsrΩ-n transcripts dynamically regulate the distribution of hnRNPs in active (chromatin bound) and inactive (in omega speckles) compartments. Here we show that a P transposon insertion in this gene's promoter (at -130 bp) in the hsrΩ05241enhancer-trap line had no effect on viability or phenotype of males or females, but the insertion-homozygous males were sterile. Testes of hsrΩ05241homozygous flies contained nonmotile sperms while their seminal vesicles were empty. RNA: RNAin situhybridization showed that the somatic cyst cells in testes of the mutant male flies contained significantly higher amounts of hsrΩ-n transcripts, and unlike the characteristic fine omega speckles in other cell types they displayed large clusters of omega speckles as typically seen after heat shock. Two of the hnRNPs, viz. HRB87F and Hrp57A, which are expressed in cyst cells, also formed large clusters in these cells in parallel with the hsrΩ-n transcripts. A complete excision of the P transposon insertion restored male fertility as well as the fine-speckled pattern of omega speckles in the cyst cells. Thein situdistribution patterns of these two hnRNPs and several other RNA-binding proteins (Hrp40, Hrb57A, S5, Sxl, SRp55 and Rb97D) were not affected by hsrΩ mutation in any of the meiotic stages in adult testes. The present studies, however, revealed an unexpected presence (in wild-type as well as mutant) of the functional form of Sxl in primary spermatocytes and an unusual distribution of HRB87F along the retracting spindle during anaphasetelophase of the first meiotic division. It appears that the P transposon insertion in the promoter region causes a misregulated overexpression of hsrΩ in cyst cells, which in turn results in excessive sequestration of hnRNPs and formation of large clusters of omega speckles in these cell nuclei. The consequent limiting availability of hnRNPs is likely totrans-dominantly affect processing of other pre-mRNAs in cyst cells. We suggest that a compromise in the activity of cyst cells due to the aberrant hnRNP distribution is responsible for the failure of individualization of sperms in hsrΩ05241mutant testes. These results further support a significant role of the noncoding hsrΩ-n transcripts in basic cellular activities, namely regulation of the availability of hnRNPs in active (chromatin bound) and inactive (in omega speckles) compartments.

Published

2001

4. Developmental regulation and complex organization of the promoter of the non-codinghsrω gene ofDrosophila melanogaster

Author

Lakhotia, S., Rajendra, T., and Prasanth, K.

Abstract

Abstract: The nucleus-limited large non-coding hsrω-n RNA product of the93D or thehsrω gene ofDrosophila melanogaster binds to a variety of RNA-binding proteins involved in nuclear RNA processing. We examined the developmental and heat shock induced expression of this gene byin situ hybridization of nonradioactively labelled riboprobe to cellular transcripts in intact embryos, larval and adult somatic tissues of wild type and an enhancer-trap line carrying thehsrω 05241 allele due to insertion of aP-LacZ-rosy + transposon at — 130 bp position of thehsrω promoter. We also examinedLacZ expression in the enhancer-trap line and in two transgenic lines carrying different lengths of thehsrω promoter upstream of theLacZ reporter. ThehsrΩ gene is expressed widely at all developmental stages; in later embryonic stages, its expression in the developing central nervous system was prominent. In spite of insertion of a big transposon in the promoter, expression of thehsrω 05241 allele in the enhancer-trap line, as revealed byin situ hybridization to hsrω transcripts in cells, was similar to that of the wild type allele in all the embryonic, larval and adult somatic tissues examined. Expression of theLacZ gene in this enhancer-trap line was similar to that of thehsrω RNA in all diploid cell types in embryos and larvae but in the polytene cells, theLacZ gene did not express at all, neither during normal development nor after heat shock. Comparison of the expression patterns ofhsrω gene and those of theLacZ reporter gene under its various promoter regions in the enhancer-trap and transgenic lines revealed a complex pattern of regulation, which seems to be essential for its dynamically varying expression in diverse cell types.

Published

2001

5. Omega speckles - a novel class of nuclear speckles containing hnRNPs associated with noncoding hsr-omega RNA in Drosophila.

Author

V, Prasanth K, K, Rajendra T, K, Lal A, and C, Lakhotia S

Abstract

Fluorescence RNA:RNA in situ hybridization studies in various larval and adult cell types of Drosophila melanogaster showed that the noncoding hsr-omega nuclear (hsromega-n) transcripts were present in the form of many small speckles. These speckles, which we name 'omega speckles', were distributed in the interchromatin space in close proximity to the chromatin. The only chromosomal site where hsromega-n transcripts localized was the 93D locus or the hsromega gene itself. The number of nucleoplasmic speckles varied in different cell types. Heat shock, which inhibits general chromosomal transcription, caused the individual speckles to coalesce into larger but fewer clusters. In extreme cases, only a single large cluster of hsromega-n transcripts localizing to the hsromega locus was seen in each nucleus. In situ immunocytochemical staining using antibodies against heterogenous nuclear RNA binding proteins (hnRNPs) like HRB87F, Hrp40, Hrb57A and S5 revealed that, in all cell types, all the hnRNPs gave a diffuse staining of chromatin areas and in addition, were present as large numbers of speckles. Colocalization studies revealed an absolute colocalization of the hnRNPs and the omegaspeckles. Heat shock caused all the hnRNPs to cluster together exactly, following the hsromega-n transcripts. Immunoprecipitation studies using the hnRNP antibodies further demonstrated a physical association of hnRNPs and hsromega transcripts. The omegaspeckles are distinct from interchromatin granules since nuclear speckles containing serine/arginine-rich SR-proteins like SC35 and SRp55 did not colocalize with the &ohgr; speckles. The speckled distribution of hnRNPs was completely disrupted in hsromega nullosomics. We conclude that the hsromega-n transcripts play essential structural and functional roles in organizing and establishing the hnRNP-containing omega speckles and thus regulate the trafficking and availability of hnRNPs and other related RNA binding proteins in the cell nucleus.

Published

2000

6. Omega speckles – a novel class of nuclear speckles containing hnRNPs associated with noncoding hsr-omega RNA in Drosophila

Author

Prasanth, K. V., Rajendra, T. K., Lal, A. K., and Lakhotia, S. C.

Abstract

Fluorescence RNA:RNA in situ hybridization studies in various larval and adult cell types of Drosophila melanogaster showed that the noncoding hsr-omega nuclear (hsrω-n) transcripts were present in the form of many small speckles. These speckles, which we name ‘omega speckles’, were distributed in the interchromatin space in close proximity to the chromatin. The only chromosomal site where hsrω-n transcripts localized was the 93D locus or the hsrω gene itself. The number of nucleoplasmic speckles varied in different cell types. Heat shock, which inhibits general chromosomal transcription, caused the individual speckles to coalesce into larger but fewer clusters. In extreme cases, only a single large cluster of hsrω-n transcripts localizing to the hsrω locus was seen in each nucleus. In situ immunocytochemical staining using antibodies against heterogenous nuclear RNA binding proteins (hnRNPs) like HRB87F, Hrp40, Hrb57A and S5 revealed that, in all cell types, all the hnRNPs gave a diffuse staining of chromatin areas and in addition, were present as large numbers of speckles. Colocalization studies revealed an absolute colocalization of the hnRNPs and the omega speckles. Heat shock caused all the hnRNPs to cluster together exactly, following the hsrω-n transcripts. Immunoprecipitation studies using the hnRNP antibodies further demonstrated a physical association of hnRNPs and hsrω transcripts. The omega speckles are distinct from interchromatin granules since nuclear speckles containing serine/arginine-rich SR-proteins like SC35 and SRp55 did not colocalize with the omega speckles. The speckled distribution of hnRNPs was completely disrupted in hsrω nullosomics. We conclude that the hsrω-n transcripts play essential structural and functional roles in organizing and establishing the hnRNP-containing omega speckles and thus regulate the trafficking and availability of hnRNPs and other related RNA binding proteins in the cell nucleus.

Published

2000

7. Abstracts of posters presented at the symposium

Author

Maiya, Bhaskar G., Chauhan, S. M. S., Bhyrappa, P., Krishnan, V., Bhardwaj, P. K., Sarkar, Sabyasachi, Pandeya, Krishna B., Mathur, Pavan, Chakravarty, Akhil R., Das, Birinchi K., Behere, Digambar V., Modi, Sandeep, Mitra, Samaresh, Modi, Sandeep, Behere, Digambar V., Mitra, Samaresh, Saxena, Anil, Modi, Sandeep, Behere, Digambar V., Mitra, S., Mazumdar, Shyamalava, Medhi, Okhil K., Mitra, Samaresh, Mazumdar, Shyamalava, Mitra, Samaresh, Madan, Anup, Modi, Sandeep, Saxena, Anil, Behere, Digamber V., Mitra, S., Pandiyan, T., Palaniandavar, M., Narayanan, K. L., Manohar, H., Ramaraj, R., Thomas, C. C., Rajagopal, S., Rajendra, T., Srinivasan, C., Ramamurthy, P., Roy, R., Saha, M. C., Panchanan, S., Roy, P. S., Balagopalakrishna, C., Rajasekharan, M. V., Agarwala, B. V., Hingorani, S., Gowda, G. A. Nagena, Ramaswamy, Y. S., Halesha, R., Gowda, N. M. N., Reddy, G. K. N., Saxena, G. C., Gupta, K. L., Srivastava, P., Gupta, V. D., Ray, M., Mukherjee, R. N., Mohanty, R. N., Dash, K. C., Kapoor, Ramesh, Yadav, S., Sood, V., Kapoor, P., Anand, B. N., Bains, R., Usha, Aggarwal, K., Garge, P., Chikate, R., Padhye, S., Savariault, J. M., De Loth, P., Tuchgues, J. P., Jain, V. K., Vaidya, M. A., Jain, S. C., Kumar, S. Kalyan, Singh, Harkesh B., Mangaonkar, K. M., Patkar, D. N., Jha, N. K., Sharma, Pankaj, Date, S. K., Deshpande, C. E., Sathaye, S. D., Deshpande, S. B., Potdar, H. S., Darshane, V. S., Dash, A. C., Nanda, R. K., Das, N. N., Gangopadhyay, S., Banerjee, P., Kulshreshtha, S. K., Zacharias, P. S., Arulsamy, N., Ramasami, T., Subramanian, V., Nair, B. U., Kanthimathi, M., Sundararajan, G., Shivasubramanian, V., Bhattacharya, R. G., Biswas, S., Armstrong, J., Holt, E. M., and Koley, A. P.

Published

1990

8. Rectal Dieulafoy's Lesion: Cause of Massive Lower Gastrointestinal Tract Haemorrhage

Author

Rajendra, T., Chung, Y.F.A., and Ong, H.S.

Published

2000