Your search keyword '"Pillalamarri V"' showing total 19 results

1. Disruption of MBD5 contributes to a spectrum of psychopathology and neurodevelopmental abnormalities

Author

Hodge, J C, Mitchell, E, Pillalamarri, V, Toler, T L, Bartel, F, Kearney, H M, Zou, Y S, Tan, W H, Hanscom, C, Kirmani, S, Hanson, R R, Skinner, S A, Rogers, R C, Everman, D B, Boyd, E, Tapp, C, Mullegama, S V, Keelean-Fuller, D, Powell, C M, Elsea, S H, Morton, C C, Gusella, J F, DuPont, B, Chaubey, A, Lin, A E, and Talkowski, M E

Published

2014

2. The genomic landscape of balanced cytogenetic abnormalities associated with human congenital anomalies.

Author

Redin, C., Brand, H., Collins, R., Kammin, T., Mitchell, E., Hodge, J.C., Hanscom, C., Pillalamarri, V., Seabra, C.M., Abbott, M.A., Abdul-Rahman, O.A., Aberg, E., Bongers, E.M.H.F., Vries, B.B.A. de, Koolen, D.A., Jongmans, M.C.J., Marcelis, C.L.M., Bon, B.W.M. van, Burgt, I. van der, Brunner, H.G., Leeuw, N. de, et al., Redin, C., Brand, H., Collins, R., Kammin, T., Mitchell, E., Hodge, J.C., Hanscom, C., Pillalamarri, V., Seabra, C.M., Abbott, M.A., Abdul-Rahman, O.A., Aberg, E., Bongers, E.M.H.F., Vries, B.B.A. de, Koolen, D.A., Jongmans, M.C.J., Marcelis, C.L.M., Bon, B.W.M. van, Burgt, I. van der, Brunner, H.G., Leeuw, N. de, and et al.

Abstract

Contains fulltext : 169855.pdf (publisher's version ) (Closed access)

Published

2017

3. The genomic landscape of balanced cytogenetic abnormalities associated with human congenital anomalies

Author

Redin, C. (Claire), Brand, H. (Harrison), Collins, R.L. (Ryan L.), Kammin, T. (Tammy), Mitchell, E. (Elyse), Hodge, J.C. (Jennelle C.), Hanscom, C. (Carrie), Pillalamarri, V. (Vamsee), Seabra, C.M. (Catarina M.), Abbott, M.-A. (Mary-Alice), Abdul-Rahman, O.A. (Omar), Aberg, E. (Erika), Adley, R. (Rhett), Alcaraz-Estrada, S.L. (Sofia L.), Alkuraya, F.S. (Fowzan S), An, Y. (Yu), Anderson, M.-A. (Mary-Anne), Antolik, C. (Caroline), Anyane-Yeboa, K. (Kwame), Atkin, J.F. (Joan), Bartell, T. (Tina), Bernstein, J.A. (Jonathan A.), Beyer, E. (Elizabeth), Blumenthal, I. (Ian), Bongers, E. (Ernie), Brilstra, E.H. (Eva H.), Brown, C.W. (Chester W.), Brüggenwirth, H.T. (Hennie), Callewaert, L., Chiang, C. (Colby), Corning, K. (Ken), Cox, H. (H.), Cuppen, E. (Edwin), Currall, B.B. (Benjamin B.), Cushing, T. (Tom), David, D. (Dezso), Deardorff, M.A. (Matthew), Dheedene, A. (Annelies), D'Hooghe, M. (Marc), Vries, B. (Boukje) de, Earl, D.L. (Dawn L.), Ferguson, H.L. (Heather L.), Fisher, H. (Heather), Fitzpatrick, D.R. (David R.), Gerrol, P. (Pamela), Giachino, D. (Daniela), Glessner, J.T. (Joseph T.), Gliem, T. (Troy), Grady, M. (Margo), Graham, B.H. (Brett H.), Griffis, C. (Cristin), Gripp, K.W. (Karen), Gropman, A.L. (Andrea L.), Hanson-Kahn, A. (Andrea), Harris, D.J. (David J.), Hayden, M.A. (Mark A.), Hill, R. (Rosamund), Hochstenbach, R. (Ron), Hoffman, J.D. (Jodi D.), Hopkin, R., Hubshman, M.W. (Monika W.), Innes, M., Irons, M. (Mira), Irving, M. (Melita), Jacobsen, J.C. (Jessie C.), Janssens, S. (Sandra), Jewett, T. (Tamison), Johnson, J.P. (John P.), Jongmans, M.C.J. (Marjolijn), Kahler, S.G. (Stephen G.), Koolen, D.A. (David), Korzelius, J. (Jerome), Kroisel, P. (Peter), Lacassie, Y. (Yves), Lawless, W. (William), Lemyre, E. (Emmanuelle), Leppig, K. (Kathy), Levin, A.V. (Alex V.), Li, H. (Haibo), Li, H. (Hong), Liao, E.C. (Eric C.), Lim, C. (Cynthia), Lose, E.J. (Edward J.), Lucente, D. (Diane), MacEra, M.J. (Michael J.), Manavalan, P. (Poornima), Mandrile, G. (Giorgia), Marcelis, C.L.M. (Carlo), Margolin, L. (Lauren), Mason, T. (Tamara), Masser-Frye, D. (Diane), McClellan, M.W. (Michael W.), Zepeda Mendoza, C.J. (Cinthya J.), Menten, B., Middelkamp, S. (Sjors), Mikami, L.R. (Liya R.), Moe, E. (Emily), Mohammed, S. (Shabaz), Mononen, T. (Tarja), Mortenson, M.E. (Megan E.), Moya, G. (Graciela), Nieuwint, A.W. (Aggie W.), Ordulu, Z. (Zehra), Parkash, S. (Sandhya), Pauker, S.P. (Susan P.), Pereira, S. (Shahrin), Perrin, D. (Danielle), Phelan, K. (Katy), Piña Aguilar, R.E. (Raul E.), Poddighe, P. (Pino), Pregno, G. (Giulia), Raskin, S. (Salmo), Reis, L. (Linda), Rhead, W. (William), Rita, D. (Debra), Renkens, I. (Ivo), Roelens, F. (Filip), Ruliera, J. (Jayla), Rump, P. (Patrick), Schilit, S.L.P. (Samantha L.P.), Shaheen, R. (Ranad), Sparkes, R. (Rebecca), Spiegel, E. (Erica), Stevens, B. (Blair), Stone, M.R. (Matthew R.), Tagoe, J. (Julia), Thakuria, J.V. (Joseph V.), Bon, B. (Bregje) van, van de Kamp, J.M. (Jiddeke M.), Van Der Burgt, I. (Ineke), Essen, T. (Ton) van, Ravenswaaij-Arts, C.M.A. (Conny) van, Van Roosmalen, M.J. (Markus J.), Vergult, S. (Sarah), Volker-Touw, C.M.L. (Catharina M.L.), Warburton, D. (Dorothy), Waterman, M.J. (Matthew J.), Wiley, S. (Susan), Wilson, A. (Anna), Yerena-De Vega, M.D.L.C.A. (Maria De La Concepcion A), Zori, R.T. (Roberto T.), Levy, B. (Brynn), Brunner, H.G. (Han), Leeuw, N. (Nicole) de, Kloosterman, W.P. (Wigard), Thorland, E.C. (Erik C.), Morton, C.C. (Cynthia), Gusella, J.F. (James), Talkowski, M.E. (Michael E.), Redin, C. (Claire), Brand, H. (Harrison), Collins, R.L. (Ryan L.), Kammin, T. (Tammy), Mitchell, E. (Elyse), Hodge, J.C. (Jennelle C.), Hanscom, C. (Carrie), Pillalamarri, V. (Vamsee), Seabra, C.M. (Catarina M.), Abbott, M.-A. (Mary-Alice), Abdul-Rahman, O.A. (Omar), Aberg, E. (Erika), Adley, R. (Rhett), Alcaraz-Estrada, S.L. (Sofia L.), Alkuraya, F.S. (Fowzan S), An, Y. (Yu), Anderson, M.-A. (Mary-Anne), Antolik, C. (Caroline), Anyane-Yeboa, K. (Kwame), Atkin, J.F. (Joan), Bartell, T. (Tina), Bernstein, J.A. (Jonathan A.), Beyer, E. (Elizabeth), Blumenthal, I. (Ian), Bongers, E. (Ernie), Brilstra, E.H. (Eva H.), Brown, C.W. (Chester W.), Brüggenwirth, H.T. (Hennie), Callewaert, L., Chiang, C. (Colby), Corning, K. (Ken), Cox, H. (H.), Cuppen, E. (Edwin), Currall, B.B. (Benjamin B.), Cushing, T. (Tom), David, D. (Dezso), Deardorff, M.A. (Matthew), Dheedene, A. (Annelies), D'Hooghe, M. (Marc), Vries, B. (Boukje) de, Earl, D.L. (Dawn L.), Ferguson, H.L. (Heather L.), Fisher, H. (Heather), Fitzpatrick, D.R. (David R.), Gerrol, P. (Pamela), Giachino, D. (Daniela), Glessner, J.T. (Joseph T.), Gliem, T. (Troy), Grady, M. (Margo), Graham, B.H. (Brett H.), Griffis, C. (Cristin), Gripp, K.W. (Karen), Gropman, A.L. (Andrea L.), Hanson-Kahn, A. (Andrea), Harris, D.J. (David J.), Hayden, M.A. (Mark A.), Hill, R. (Rosamund), Hochstenbach, R. (Ron), Hoffman, J.D. (Jodi D.), Hopkin, R., Hubshman, M.W. (Monika W.), Innes, M., Irons, M. (Mira), Irving, M. (Melita), Jacobsen, J.C. (Jessie C.), Janssens, S. (Sandra), Jewett, T. (Tamison), Johnson, J.P. (John P.), Jongmans, M.C.J. (Marjolijn), Kahler, S.G. (Stephen G.), Koolen, D.A. (David), Korzelius, J. (Jerome), Kroisel, P. (Peter), Lacassie, Y. (Yves), Lawless, W. (William), Lemyre, E. (Emmanuelle), Leppig, K. (Kathy), Levin, A.V. (Alex V.), Li, H. (Haibo), Li, H. (Hong), Liao, E.C. (Eric C.), Lim, C. (Cynthia), Lose, E.J. (Edward J.), Lucente, D. (Diane), MacEra, M.J. (Michael J.), Manavalan, P. (Poornima), Mandrile, G. (Giorgia), Marcelis, C.L.M. (Carlo), Margolin, L. (Lauren), Mason, T. (Tamara), Masser-Frye, D. (Diane), McClellan, M.W. (Michael W.), Zepeda Mendoza, C.J. (Cinthya J.), Menten, B., Middelkamp, S. (Sjors), Mikami, L.R. (Liya R.), Moe, E. (Emily), Mohammed, S. (Shabaz), Mononen, T. (Tarja), Mortenson, M.E. (Megan E.), Moya, G. (Graciela), Nieuwint, A.W. (Aggie W.), Ordulu, Z. (Zehra), Parkash, S. (Sandhya), Pauker, S.P. (Susan P.), Pereira, S. (Shahrin), Perrin, D. (Danielle), Phelan, K. (Katy), Piña Aguilar, R.E. (Raul E.), Poddighe, P. (Pino), Pregno, G. (Giulia), Raskin, S. (Salmo), Reis, L. (Linda), Rhead, W. (William), Rita, D. (Debra), Renkens, I. (Ivo), Roelens, F. (Filip), Ruliera, J. (Jayla), Rump, P. (Patrick), Schilit, S.L.P. (Samantha L.P.), Shaheen, R. (Ranad), Sparkes, R. (Rebecca), Spiegel, E. (Erica), Stevens, B. (Blair), Stone, M.R. (Matthew R.), Tagoe, J. (Julia), Thakuria, J.V. (Joseph V.), Bon, B. (Bregje) van, van de Kamp, J.M. (Jiddeke M.), Van Der Burgt, I. (Ineke), Essen, T. (Ton) van, Ravenswaaij-Arts, C.M.A. (Conny) van, Van Roosmalen, M.J. (Markus J.), Vergult, S. (Sarah), Volker-Touw, C.M.L. (Catharina M.L.), Warburton, D. (Dorothy), Waterman, M.J. (Matthew J.), Wiley, S. (Susan), Wilson, A. (Anna), Yerena-De Vega, M.D.L.C.A. (Maria De La Concepcion A), Zori, R.T. (Roberto T.), Levy, B. (Brynn), Brunner, H.G. (Han), Leeuw, N. (Nicole) de, Kloosterman, W.P. (Wigard), Thorland, E.C. (Erik C.), Morton, C.C. (Cynthia), Gusella, J.F. (James), and Talkowski, M.E. (Michael E.)

Abstract

Despite the clinical significance of balanced chromosomal abnormalities (BCAs), their characterization has largely been restricted to cytogenetic resolution. We explored the landscape of BCAs at nucleotide resolution in 273 subjects with a spectrum of congenital anomalies. Whole-genome sequencing revised 93% of karyotypes and demonstrated complexity that was cryptic to karyotyping in 21% of BCAs, highlighting the limitations of conventional cytogenetic approaches. At least 33.9% of BCAs resulted in gene disruption that likely contributed to the developmental phenotype, 5.2% were associated with pathogenic genomic imbalances, and 7.3% disrupted topologically associated domains (TADs) encompassing known syndromic loci. Remarkably, BCA br

Published

2017

4. Prenatal diagnosis of chromothripsis, with nine breaks characterized by karyotyping, FISH, microarray and whole-genome sequencing

Author

Macera, M.J., Sobrino, A., Levy, B., Jobanputra, V., Aggarwal, V., Mills, A., Esteves, C., Hanscom, C., Pereira, S., Pillalamarri, V., Ordulu, Z., Morton, C., Talkowski, M., and Warburton, D.

Subjects

Adult, Genome, Chromosome Disorders, Sequence Analysis, DNA, Article, Translocation, Genetic, Pregnancy, Karyotyping, Prenatal Diagnosis, Humans, Abnormalities, Multiple, Female, In Situ Hybridization, Fluorescence, Oligonucleotide Array Sequence Analysis

Published

2015

5. Genomic and Functional Overlap between Somatic and Germline Chromosomal Rearrangements

Author

Heesch, S. van, Simonis, M., Roosmalen, M.J. van, Pillalamarri, V., Brand, H., Kuijk, E.W., Luca, K.L. de, Lansu, N., Braat, A.K., Menelaou, A., Hao, W., Korving, J., Snijder, S., Veken, L.T. van der, Hochstenbach, R., Knegt, A.C., Duran, K., Renkens, I., Alekozai, N., Jager, M. de, Vergult, S., Menten, B., Bruijn, E. de, Boymans, S., Ippel, E., Binsbergen, E. van, Talkowski, M.E., Lichtenbelt, K., Cuppen, E., Kloosterman, W.P., Heesch, S. van, Simonis, M., Roosmalen, M.J. van, Pillalamarri, V., Brand, H., Kuijk, E.W., Luca, K.L. de, Lansu, N., Braat, A.K., Menelaou, A., Hao, W., Korving, J., Snijder, S., Veken, L.T. van der, Hochstenbach, R., Knegt, A.C., Duran, K., Renkens, I., Alekozai, N., Jager, M. de, Vergult, S., Menten, B., Bruijn, E. de, Boymans, S., Ippel, E., Binsbergen, E. van, Talkowski, M.E., Lichtenbelt, K., Cuppen, E., and Kloosterman, W.P.

Abstract

Contains fulltext : 139109.pdf (publisher's version ) (Open Access), Genomic rearrangements are a common cause of human congenital abnormalities. However, their origin and consequences are poorly understood. We performed molecular analysis of two patients with congenital disease who carried de novo genomic rearrangements. We found that the rearrangements in both patients hit genes that are recurrently rearranged in cancer (ETV1, FOXP1, and microRNA cluster C19MC) and drive formation of fusion genes similar to those described in cancer. Subsequent analysis of a large set of 552 de novo germline genomic rearrangements underlying congenital disorders revealed enrichment for genes rearranged in cancer and overlap with somatic cancer breakpoints. Breakpoints of common (inherited) germline structural variations also overlap with cancer breakpoints but are depleted for cancer genes. We propose that the same genomic positions are prone to genomic rearrangements in germline and soma but that timing and context of breakage determines whether developmental defects or cancer are promoted.

Published

2014

6. Disruption of MBD5 contributes to a spectrum of psychopathology and neurodevelopmental abnormalities

Author

Hodge, J C, primary, Mitchell, E, additional, Pillalamarri, V, additional, Toler, T L, additional, Bartel, F, additional, Kearney, H M, additional, Zou, Y S, additional, Tan, W H, additional, Hanscom, C, additional, Kirmani, S, additional, Hanson, R R, additional, Skinner, S A, additional, Rogers, R C, additional, Everman, D B, additional, Boyd, E, additional, Tapp, C, additional, Mullegama, S V, additional, Keelean-Fuller, D, additional, Powell, C M, additional, Elsea, S H, additional, Morton, C C, additional, Gusella, J F, additional, DuPont, B, additional, Chaubey, A, additional, Lin, A E, additional, and Talkowski, M E, additional

Published

2013

7. A leucine responsive small RNA AbcR200 regulates expression of the lactate utilization (lut) operon in Acinetobacter baumannii DS002.

Author

Yakkala HN, Madikonda AK, Behera SR, Pillalamarri V, Mohammad KG, Dhurve G, Tammineni P, Pakala SB, and Siddavattam D

Abstract

Noncoding small RNAs are essential for modulating bacterial gene expression, especially under carbon and nutrient-limited conditions. In this study, by employing both in silico and molecular hybridization tools, we identified a carbon source responsive small RNA in A. baumannii DS002. Expression of corresponding gene, abcR200, located at the intergenic region of omt (O-methyltransferase) and orf72 genes, is under the transcriptional control of a global transcriptional factor, Leucine Responsive Regulatory Protein (Lrp). A sequence motif that serves as a target for Lrp was found overlapping the abcR200 promoter (P abcR200 ). Chromatin immunoprecipitation (ChIP) demonstrated that Lrp oligomers, formed under low leucine conditions, strongly interacted to the P abcR200 . However, the observed interactions were disrupted in the presence of leucine, as leucine promoted dissociation of Lrp to monomers and dimers, the conformation unfavourable to interact with P abcR200. The abcR200 promoter activity increased with increase of exogenous leucine concentrations, and at 2 mM maximum promoter activity was observed. The AbcR200 target mRNAs were identified by analysing the transcriptome of abcR200 negative strain of A. baumannii. Intriguingly, in abcR200 negative background, expression of lut (lactate utilization) mRNA has increased, suggesting that lut mRNA as one of the mRNA targets for AbcR200. Consistent of this observation, there existed extensive sequence complementarity between AbcR200 and lut mRNA, especially in the regions coding LutP, LutE and LutR. In support of the observed sequence complementarity, the levels of lut mRNA encoded proteins got elevated in abcR200 negative HS002 strains suggesting a role for AbcR200 in translational inhibition of lut mRNA., Competing Interests: Conflict of Interest Statement The authors of this paper declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported herein. This encompasses any financial arrangements, affiliations, or involvements with organizations that may have influenced the research process, analysis, or interpretation of results. Additionally, the authors affirm that they have not received any financial support or other benefits from entities with an interest in the subject matter discussed in this paper., (Copyright © 2025 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2025

8. Deleterious heteroplasmic mitochondrial mutations are associated with an increased risk of overall and cancer-specific mortality.

Author

Hong YS, Battle SL, Shi W, Puiu D, Pillalamarri V, Xie J, Pankratz N, Lake NJ, Lek M, Rotter JI, Rich SS, Kooperberg C, Reiner AP, Auer PL, Heard-Costa N, Liu C, Lai M, Murabito JM, Levy D, Grove ML, Alonso A, Gibbs R, Dugan-Perez S, Gondek LP, Guallar E, and Arking DE

Subjects

Humans, DNA, Mitochondrial genetics, Heteroplasmy, Mutation, Mitochondria genetics, Leukemia genetics

Abstract

Mitochondria carry their own circular genome and disruption of the mitochondrial genome is associated with various aging-related diseases. Unlike the nuclear genome, mitochondrial DNA (mtDNA) can be present at 1000 s to 10,000 s copies in somatic cells and variants may exist in a state of heteroplasmy, where only a fraction of the DNA molecules harbors a particular variant. We quantify mtDNA heteroplasmy in 194,871 participants in the UK Biobank and find that heteroplasmy is associated with a 1.5-fold increased risk of all-cause mortality. Additionally, we functionally characterize mtDNA single nucleotide variants (SNVs) using a constraint-based score, mitochondrial local constraint score sum (MSS) and find it associated with all-cause mortality, and with the prevalence and incidence of cancer and cancer-related mortality, particularly leukemia. These results indicate that mitochondria may have a functional role in certain cancers, and mitochondrial heteroplasmic SNVs may serve as a prognostic marker for cancer, especially for leukemia., (© 2023. Springer Nature Limited.)

Published

2023

9. Whole-exome sequencing in 415,422 individuals identifies rare variants associated with mitochondrial DNA copy number.

Author

Pillalamarri V, Shi W, Say C, Yang S, Lane J, Guallar E, Pankratz N, and Arking DE

Subjects

Humans, Child, SAM Domain and HD Domain-Containing Protein 1 genetics, Exome Sequencing, Mitochondria genetics, Exome genetics, Syndrome, Exodeoxyribonucleases genetics, DNA, Mitochondrial genetics, DNA Copy Number Variations genetics

Abstract

Inter-individual variation in the number of copies of the mitochondrial genome, called mitochondrial DNA copy number (mtDNA-CN), reflects mitochondrial function and has been associated with various aging-related diseases. We examined 415,422 exomes of self-reported White ancestry individuals from the UK Biobank and tested the impact of rare variants, at the level of single variants and through aggregate variant-set tests, on mtDNA-CN. A survey across nine variant sets tested enrichment of putatively causal variants and identified 14 genes at experiment-wide significance and three genes at marginal significance. These included associations at known mtDNA depletion syndrome genes (mtDNA helicase TWNK , p = 1.1 × 10 -30 ; mitochondrial transcription factor TFAM , p = 4.3 × 10 -15 ; mtDNA maintenance exonuclease MGME1 , p = 2.0 × 10 -6 ) and the V617F dominant gain-of-function mutation in the tyrosine kinase JAK2 (p = 2.7 × 10 -17 ), associated with myeloproliferative disease. Novel genes included the ATP-dependent protease CLPX (p = 8.4 × 10 -9 ), involved in mitochondrial proteome quality, and the mitochondrial adenylate kinase AK2 (p = 4.7 × 10 -8 ), involved in hematopoiesis. The most significant association was a missense variant in SAMHD1 (p = 4.2 × 10 -28 ), found on a rare, 1.2-Mb shared ancestral haplotype on chromosome 20. SAMHD1 encodes a cytoplasmic host restriction factor involved in viral defense response and the mitochondrial nucleotide salvage pathway, and is associated with Aicardi-Goutières syndrome 5, a childhood encephalopathy and chronic inflammatory response disorder. Rare variants were enriched in Mendelian mtDNA depletion syndrome loci, and these variants implicated core processes in mtDNA replication, nucleoid structure formation, and maintenance. These data indicate that strong-effect mutations from the nuclear genome contribute to the genetic architecture of mtDNA-CN., Competing Interests: The authors declare no competing interests., (© 2022 The Author(s).)

Published

2022

10. Consistent RNA sequencing contamination in GTEx and other data sets.

Author

Nieuwenhuis TO, Yang SY, Verma RX, Pillalamarri V, Arking DE, Rosenberg AZ, McCall MN, and Halushka MK

Subjects

Genotype, High-Throughput Nucleotide Sequencing, Humans, Polymorphism, Single Nucleotide, Sequence Analysis, RNA, Single-Cell Analysis, DNA Contamination, RNA genetics

Abstract

A challenge of next generation sequencing is read contamination. We use Genotype-Tissue Expression (GTEx) datasets and technical metadata along with RNA-seq datasets from other studies to understand factors that contribute to contamination. Here we report, of 48 analyzed tissues in GTEx, 26 have variant co-expression clusters of four highly expressed and pancreas-enriched genes (PRSS1, PNLIP, CLPS, and/or CELA3A). Fourteen additional highly expressed genes from other tissues also indicate contamination. Sample contamination is strongly associated with a sample being sequenced on the same day as a tissue that natively expresses those genes. Discrepant SNPs across four contaminating genes validate the contamination. Low-level contamination affects ~40% of samples and leads to numerous eQTL assignments in inappropriate tissues among these 18 genes. This type of contamination occurs widely, impacting bulk and single cell (scRNA-seq) data set analysis. In conclusion, highly expressed, tissue-enriched genes basally contaminate GTEx and other datasets impacting analyses.

Published

2020

11. Bengamides display potent activity against drug-resistant Mycobacterium tuberculosis.

Author

Quan DH, Nagalingam G, Luck I, Proschogo N, Pillalamarri V, Addlagatta A, Martinez E, Sintchenko V, Rutledge PJ, and Triccas JA

Subjects

Antitubercular Agents chemistry, Azepines chemistry, Drug Interactions, Microbial Sensitivity Tests, Antitubercular Agents pharmacology, Azepines pharmacology, Drug Resistance, Bacterial drug effects, Mycobacterium tuberculosis drug effects

Abstract

Mycobacterium tuberculosis infects over 10 million people annually and kills more people each year than any other human pathogen. The current tuberculosis (TB) vaccine is only partially effective in preventing infection, while current TB treatment is problematic in terms of length, complexity and patient compliance. There is an urgent need for new drugs to combat the burden of TB disease and the natural environment has re-emerged as a rich source of bioactive molecules for development of lead compounds. In this study, one species of marine sponge from the Tedania genus was found to yield samples with exceptionally potent activity against M. tuberculosis. Bioassay-guided fractionation identified bengamide B as the active component, which displayed activity in the nanomolar range against both drug-sensitive and drug-resistant M. tuberculosis. The active compound inhibited in vitro activity of M. tuberculosis MetAP1c protein, suggesting the potent inhibitory action may be due to interference with methionine aminopeptidase activity. Tedania-derived bengamide B was non-toxic against human cell lines, synergised with rifampicin for in vitro inhibition of bacterial growth and reduced intracellular replication of M. tuberculosis. Thus, bengamides isolated from Tedania sp. show significant potential as a new class of compounds for the treatment of drug-resistant M. tuberculosis.

Published

2019

12. Structural Chromosomal Rearrangements Require Nucleotide-Level Resolution: Lessons from Next-Generation Sequencing in Prenatal Diagnosis.

Author

Ordulu Z, Kammin T, Brand H, Pillalamarri V, Redin CE, Collins RL, Blumenthal I, Hanscom C, Pereira S, Bradley I, Crandall BF, Gerrol P, Hayden MA, Hussain N, Kanengisser-Pines B, Kantarci S, Levy B, Macera MJ, Quintero-Rivera F, Spiegel E, Stevens B, Ulm JE, Warburton D, Wilkins-Haug LE, Yachelevich N, Gusella JF, Talkowski ME, and Morton CC

Subjects

Alleles, Chromosome Mapping, Congenital Abnormalities diagnosis, Female, Gene Expression Regulation, Genetic Testing, Genome, Human, Genomics, High-Throughput Nucleotide Sequencing, Humans, Karyotyping, Male, Pregnancy, SOX9 Transcription Factor genetics, SOX9 Transcription Factor metabolism, Sequence Analysis, DNA, Translocation, Genetic, Chromosome Aberrations, Congenital Abnormalities genetics, Gene Rearrangement, Nucleotides genetics, Prenatal Diagnosis methods

Abstract

In this exciting era of "next-gen cytogenetics," integrating genomic sequencing into the prenatal diagnostic setting is possible within an actionable time frame and can provide precise delineation of balanced chromosomal rearrangements at the nucleotide level. Given the increased risk of congenital abnormalities in newborns with de novo balanced chromosomal rearrangements, comprehensive interpretation of breakpoints could substantially improve prediction of phenotypic outcomes and support perinatal medical care. Herein, we present and evaluate sequencing results of balanced chromosomal rearrangements in ten prenatal subjects with respect to the location of regulatory chromatin domains (topologically associated domains [TADs]). The genomic material from all subjects was interpreted to be "normal" by microarray analyses, and their rearrangements would not have been detected by cell-free DNA (cfDNA) screening. The findings of our systematic approach correlate with phenotypes of both pregnancies with untoward outcomes (5/10) and with healthy newborns (3/10). Two pregnancies, one with a chromosomal aberration predicted to be of unknown clinical significance and another one predicted to be likely benign, were terminated prior to phenotype-genotype correlation (2/10). We demonstrate that the clinical interpretation of structural rearrangements should not be limited to interruption, deletion, or duplication of specific genes and should also incorporate regulatory domains of the human genome with critical ramifications for the control of gene expression. As detailed in this study, our molecular approach to both detecting and interpreting the breakpoints of structural rearrangements yields unparalleled information in comparison to other commonly used first-tier diagnostic methods, such as non-invasive cfDNA screening and microarray analysis, to provide improved genetic counseling for phenotypic outcome in the prenatal setting., (Copyright © 2016 American Society of Human Genetics. All rights reserved.)

Published

2016

13. Estrogen-related receptor gamma implicated in a phenotype including hearing loss and mild developmental delay.

Author

Schilit SL, Currall BB, Yao R, Hanscom C, Collins RL, Pillalamarri V, Lee DY, Kammin T, Zepeda-Mendoza CJ, Mononen T, Nolan LS, Gusella JF, Talkowski ME, Shen J, and Morton CC

Subjects

Adult, Cell Line, Tumor, Chromosome Breakpoints, Chromosomes, Human, Pair 1 genetics, Chromosomes, Human, Pair 5 genetics, Developmental Disabilities diagnosis, Female, Hearing Loss diagnosis, Humans, Infant, Newborn, Male, Middle Aged, Pedigree, Syndrome, Translocation, Genetic, Developmental Disabilities genetics, Hearing Loss genetics, Phenotype, Receptors, Estrogen genetics

Abstract

Analysis of chromosomal rearrangements has been highly successful in identifying genes involved in many congenital abnormalities including hearing loss. Herein, we report a subject, designated DGAP242, with congenital hearing loss (HL) and a de novo balanced translocation 46,XX,t(1;5)(q32;q15)dn. Using multiple next-generation sequencing techniques, we obtained high resolution of the breakpoints. This revealed disruption of the orphan receptor ESRRG on chromosome 1, which is differentially expressed in inner ear hair cells and has previously been implicated in HL, and disruption of KIAA0825 on chromosome 5. Given the translocation breakpoints and supporting literature, disruption of ESRRG is the most likely cause for DGAP242's phenotype and implicates ESRRG in a monogenic form of congenital HL, although a putative contributory role for KIAA0825 in the subject's disorder cannot be excluded.

Published

2016

14. Actin capping protein CAPZB regulates cell morphology, differentiation, and neural crest migration in craniofacial morphogenesis†.

Author

Mukherjee K, Ishii K, Pillalamarri V, Kammin T, Atkin JF, Hickey SE, Xi QJ, Zepeda CJ, Gusella JF, Talkowski ME, Morton CC, Maas RL, and Liao EC

Subjects

Animals, Cleft Palate genetics, Cleft Palate metabolism, Disease Models, Animal, Female, Head physiology, Humans, Infant, Micrognathism genetics, Micrognathism metabolism, Muscle Hypotonia genetics, Muscle Hypotonia metabolism, Mutation, Neural Crest metabolism, Neural Crest physiology, Sequence Analysis, DNA, Syndrome, Zebrafish embryology, Zebrafish metabolism, Zebrafish physiology, CapZ Actin Capping Protein genetics, Cell Differentiation, Head embryology, Morphogenesis, Neural Crest embryology

Abstract

CAPZB is an actin-capping protein that caps the growing end of F-actin and modulates the cytoskeleton and tethers actin filaments to the Z-line of the sarcomere in muscles. Whole-genome sequencing was performed on a subject with micrognathia, cleft palate and hypotonia that harbored a de novo, balanced chromosomal translocation that disrupts the CAPZB gene. The function of capzb was analyzed in the zebrafish model. capzb(-/-) mutants exhibit both craniofacial and muscle defects that recapitulate the phenotypes observed in the human subject. Loss of capzb affects cell morphology, differentiation and neural crest migration. Differentiation of both myogenic stem cells and neural crest cells requires capzb. During palate morphogenesis, defective cranial neural crest cell migration in capzb(-/-) mutants results in loss of the median cell population, creating a cleft phenotype. capzb is also required for trunk neural crest migration, as evident from melanophores disorganization in capzb(-/-) mutants. In addition, capzb over-expression results in embryonic lethality. Therefore, proper capzb dosage is important during embryogenesis, and regulates both cell behavior and tissue morphogenesis., (© The Author 2016. Published by Oxford University Press. All rights reserved. For Permissions, please email: journals.permissions@oup.com.)

Published

2016

15. Paired-Duplication Signatures Mark Cryptic Inversions and Other Complex Structural Variation.

Author

Brand H, Collins RL, Hanscom C, Rosenfeld JA, Pillalamarri V, Stone MR, Kelley F, Mason T, Margolin L, Eggert S, Mitchell E, Hodge JC, Gusella JF, Sanders SJ, and Talkowski ME

Subjects

Cohort Studies, DNA Repair genetics, Gene Library, Humans, Child Development Disorders, Pervasive genetics, Chromosome Inversion genetics, DNA Copy Number Variations genetics, Genetic Markers genetics, Segmental Duplications, Genomic genetics

Abstract

Copy-number variants (CNVs) have been the predominant focus of genetic studies of structural variation, and chromosomal microarray (CMA) for genome-wide CNV detection is the recommended first-tier genetic diagnostic screen in neurodevelopmental disorders. We compared CNVs observed by CMA to the structural variation detected by whole-genome large-insert sequencing in 259 individuals diagnosed with autism spectrum disorder (ASD) from the Simons Simplex Collection. These analyses revealed a diverse landscape of complex duplications in the human genome. One remarkably common class of complex rearrangement, which we term dupINVdup, involves two closely located duplications ("paired duplications") that flank the breakpoints of an inversion. This complex variant class is cryptic to CMA, but we observed it in 8.1% of all subjects. We also detected other paired-duplication signatures and duplication-mediated complex rearrangements in 15.8% of all ASD subjects. Breakpoint analysis showed that the predominant mechanism of formation of these complex duplication-associated variants was microhomology-mediated repair. On the basis of the striking prevalence of dupINVdups in this cohort, we explored the landscape of all inversion variation among the 235 highest-quality libraries and found abundant complexity among these variants: only 39.3% of inversions were canonical, or simple, inversions without additional rearrangement. Collectively, these findings indicate that dupINVdups, as well as other complex duplication-associated rearrangements, represent relatively common sources of genomic variation that is cryptic to population-based microarray and low-depth whole-genome sequencing. They also suggest that paired-duplication signatures detected by CMA warrant further scrutiny in genetic diagnostic testing given that they might mark complex rearrangements of potential clinical relevance., (Copyright © 2015 The American Society of Human Genetics. Published by Elsevier Inc. All rights reserved.)

Published

2015

16. Genomic and functional overlap between somatic and germline chromosomal rearrangements.

Author

van Heesch S, Simonis M, van Roosmalen MJ, Pillalamarri V, Brand H, Kuijk EW, de Luca KL, Lansu N, Braat AK, Menelaou A, Hao W, Korving J, Snijder S, van der Veken LT, Hochstenbach R, Knegt AC, Duran K, Renkens I, Alekozai N, Jager M, Vergult S, Menten B, de Bruijn E, Boymans S, Ippel E, van Binsbergen E, Talkowski ME, Lichtenbelt K, Cuppen E, and Kloosterman WP

Subjects

Animals, Chromosome Breakpoints, DNA-Binding Proteins genetics, Forkhead Transcription Factors genetics, HEK293 Cells, Humans, MicroRNAs genetics, Repressor Proteins genetics, Transcription Factors genetics, Zebrafish, Chromosome Aberrations, Chromosomes, Human genetics, Congenital Abnormalities genetics, Gene Rearrangement, Genome, Human, Germ-Line Mutation

Abstract

Genomic rearrangements are a common cause of human congenital abnormalities. However, their origin and consequences are poorly understood. We performed molecular analysis of two patients with congenital disease who carried de novo genomic rearrangements. We found that the rearrangements in both patients hit genes that are recurrently rearranged in cancer (ETV1, FOXP1, and microRNA cluster C19MC) and drive formation of fusion genes similar to those described in cancer. Subsequent analysis of a large set of 552 de novo germline genomic rearrangements underlying congenital disorders revealed enrichment for genes rearranged in cancer and overlap with somatic cancer breakpoints. Breakpoints of common (inherited) germline structural variations also overlap with cancer breakpoints but are depleted for cancer genes. We propose that the same genomic positions are prone to genomic rearrangements in germline and soma but that timing and context of breakage determines whether developmental defects or cancer are promoted., (Copyright © 2014 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2014

17. Cryptic and complex chromosomal aberrations in early-onset neuropsychiatric disorders.

Author

Brand H, Pillalamarri V, Collins RL, Eggert S, O'Dushlaine C, Braaten EB, Stone MR, Chambert K, Doty ND, Hanscom C, Rosenfeld JA, Ditmars H, Blais J, Mills R, Lee C, Gusella JF, McCarroll S, Smoller JW, Talkowski ME, and Doyle AE

Subjects

Comparative Genomic Hybridization, Genome, Human, Humans, Mental Disorders epidemiology, Microarray Analysis, Neurodegenerative Diseases epidemiology, Phenotype, United States epidemiology, Age of Onset, Chromosome Aberrations, Chromosomes, Human genetics, DNA Copy Number Variations genetics, Mental Disorders genetics, Neurodegenerative Diseases genetics

Abstract

Structural variation (SV) is a significant component of the genetic etiology of both neurodevelopmental and psychiatric disorders; however, routine guidelines for clinical genetic screening have been established only in the former category. Genome-wide chromosomal microarray (CMA) can detect genomic imbalances such as copy-number variants (CNVs), but balanced chromosomal abnormalities (BCAs) still require karyotyping for clinical detection. Moreover, submicroscopic BCAs and subarray threshold CNVs are intractable, or cryptic, to both CMA and karyotyping. Here, we performed whole-genome sequencing using large-insert jumping libraries to delineate both cytogenetically visible and cryptic SVs in a single test among 30 clinically referred youth representing a range of severe neuropsychiatric conditions. We detected 96 SVs per person on average that passed filtering criteria above our highest-confidence resolution (6,305 bp) and an additional 111 SVs per genome below this resolution. These SVs rearranged 3.8 Mb of genomic sequence and resulted in 42 putative loss-of-function (LoF) or gain-of-function mutations per person. We estimate that 80% of the LoF variants were cryptic to clinical CMA. We found myriad complex and cryptic rearrangements, including a "paired" duplication (360 kb, 169 kb) that flanks a 5.25 Mb inversion that appears in 7 additional cases from clinical CNV data among 47,562 individuals. Following convergent genomic profiling of these independent clinical CNV data, we interpreted three SVs to be of potential clinical significance. These data indicate that sequence-based delineation of the full SV mutational spectrum warrants exploration in youth referred for neuropsychiatric evaluation and clinical diagnostic SV screening more broadly., (Copyright © 2014 The American Society of Human Genetics. Published by Elsevier Inc. All rights reserved.)

Published

2014

18. Molecular analysis of a deletion hotspot in the NRXN1 region reveals the involvement of short inverted repeats in deletion CNVs.

Author

Chen X, Shen Y, Zhang F, Chiang C, Pillalamarri V, Blumenthal I, Talkowski M, Wu BL, and Gusella JF

Subjects

Calcium-Binding Proteins, Cohort Studies, DNA Replication genetics, DNA, B-Form genetics, DNA, Single-Stranded genetics, Exons, Genetic Predisposition to Disease, Genomic Instability, Humans, Neural Cell Adhesion Molecules, Terminal Repeat Sequences, Cell Adhesion Molecules, Neuronal genetics, DNA Copy Number Variations, Inverted Repeat Sequences, Mental Disorders genetics, Nerve Tissue Proteins genetics, Sequence Deletion

Abstract

NRXN1 microdeletions occur at a relatively high frequency and confer increased risk for neurodevelopmental and neurobehavioral abnormalities. The mechanism that makes NRXN1 a deletion hotspot is unknown. Here, we identified deletions of the NRXN1 region in affected cohorts, confirming a strong association with the autism spectrum and other neurodevelopmental disorders. Interestingly, deletions in both affected and control individuals were clustered in the 5' portion of NRXN1 and its immediate upstream region. To explore the mechanism of deletion, we mapped and analyzed the breakpoints of 32 deletions. At the deletion breakpoints, frequent microhomology (68.8%, 2-19 bp) suggested predominant mechanisms of DNA replication error and/or microhomology-mediated end-joining. Long terminal repeat (LTR) elements, unique non-B-DNA structures, and MEME-defined sequence motifs were significantly enriched, but Alu and LINE sequences were not. Importantly, small-size inverted repeats (minus self chains, minus sequence motifs, and partial complementary sequences) were significantly overrepresented in the vicinity of NRXN1 region deletion breakpoints, suggesting that, although they are not interrupted by the deletion process, such inverted repeats can predispose a region to genomic instability by mediating single-strand DNA looping via the annealing of partially reverse complementary strands and the promoting of DNA replication fork stalling and DNA replication error. Our observations highlight the potential importance of inverted repeats of variable sizes in generating a rearrangement hotspot in which individual breakpoints are not recurrent. Mechanisms that involve short inverted repeats in initiating deletion may also apply to other deletion hotspots in the human genome., (Copyright © 2013 The American Society of Human Genetics. Published by Elsevier Inc. All rights reserved.)

Published

2013

19. Sequencing chromosomal abnormalities reveals neurodevelopmental loci that confer risk across diagnostic boundaries.

Author

Talkowski ME, Rosenfeld JA, Blumenthal I, Pillalamarri V, Chiang C, Heilbut A, Ernst C, Hanscom C, Rossin E, Lindgren AM, Pereira S, Ruderfer D, Kirby A, Ripke S, Harris DJ, Lee JH, Ha K, Kim HG, Solomon BD, Gropman AL, Lucente D, Sims K, Ohsumi TK, Borowsky ML, Loranger S, Quade B, Lage K, Miles J, Wu BL, Shen Y, Neale B, Shaffer LG, Daly MJ, Morton CC, and Gusella JF

Subjects

Autistic Disorder diagnosis, Autistic Disorder genetics, Child, Child Development Disorders, Pervasive diagnosis, Chromosome Breakage, Chromosome Deletion, DNA Copy Number Variations, Genetic Predisposition to Disease, Genome-Wide Association Study, Humans, Nervous System growth & development, Schizophrenia genetics, Sequence Analysis, DNA, Signal Transduction, Child Development Disorders, Pervasive genetics, Chromosome Aberrations

Abstract

Balanced chromosomal abnormalities (BCAs) represent a relatively untapped reservoir of single-gene disruptions in neurodevelopmental disorders (NDDs). We sequenced BCAs in patients with autism or related NDDs, revealing disruption of 33 loci in four general categories: (1) genes previously associated with abnormal neurodevelopment (e.g., AUTS2, FOXP1, and CDKL5), (2) single-gene contributors to microdeletion syndromes (MBD5, SATB2, EHMT1, and SNURF-SNRPN), (3) novel risk loci (e.g., CHD8, KIRREL3, and ZNF507), and (4) genes associated with later-onset psychiatric disorders (e.g., TCF4, ZNF804A, PDE10A, GRIN2B, and ANK3). We also discovered among neurodevelopmental cases a profoundly increased burden of copy-number variants from these 33 loci and a significant enrichment of polygenic risk alleles from genome-wide association studies of autism and schizophrenia. Our findings suggest a polygenic risk model of autism and reveal that some neurodevelopmental genes are sensitive to perturbation by multiple mutational mechanisms, leading to variable phenotypic outcomes that manifest at different life stages., (Copyright © 2012 Elsevier Inc. All rights reserved.)

Published

2012