Your search keyword '"Sergey Batalov"' showing total 20 results

1. Scalable, high quality, whole genome sequencing from archived, newborn, dried blood spots

Author

Yan Ding, Mallory Owen, Jennie Le, Sergey Batalov, Kevin Chau, Yong Hyun Kwon, Lucita Van Der Kraan, Zaira Bezares-Orin, Zhanyang Zhu, Narayanan Veeraraghavan, Shareef Nahas, Matthew Bainbridge, Joe Gleeson, Rebecca J. Baer, Gretchen Bandoli, Christina Chambers, and Stephen F. Kingsmore

Subjects

Medicine, Genetics, QH426-470

Abstract

Abstract Universal newborn screening (NBS) is a highly successful public health intervention. Archived dried bloodspots (DBS) collected for NBS represent a rich resource for population genomic studies. To fully harness this resource in such studies, DBS must yield high-quality genomic DNA (gDNA) for whole genome sequencing (WGS). In this pilot study, we hypothesized that gDNA of sufficient quality and quantity for WGS could be extracted from archived DBS up to 20 years old without PCR (Polymerase Chain Reaction) amplification. We describe simple methods for gDNA extraction and WGS library preparation from several types of DBS. We tested these methods in DBS from 25 individuals who had previously undergone diagnostic, clinical WGS and 29 randomly selected DBS cards collected for NBS from the California State Biobank. While gDNA from DBS had significantly less yield than from EDTA blood from the same individuals, it was of sufficient quality and quantity for WGS without PCR. All samples DBS yielded WGS that met quality control metrics for high-confidence variant calling. Twenty-eight variants of various types that had been reported clinically in 19 samples were recapitulated in WGS from DBS. There were no significant effects of age or paper type on WGS quality. Archived DBS appear to be a suitable sample type for WGS in population genomic studies.

Published

2023

2. An automated 13.5 hour system for scalable diagnosis and acute management guidance for genetic diseases

Author

Mallory J. Owen, Sebastien Lefebvre, Christian Hansen, Chris M. Kunard, David P. Dimmock, Laurie D. Smith, Gunter Scharer, Rebecca Mardach, Mary J. Willis, Annette Feigenbaum, Anna-Kaisa Niemi, Yan Ding, Luca Van Der Kraan, Katarzyna Ellsworth, Lucia Guidugli, Bryan R. Lajoie, Timothy K. McPhail, Shyamal S. Mehtalia, Kevin K. Chau, Yong H. Kwon, Zhanyang Zhu, Sergey Batalov, Shimul Chowdhury, Seema Rego, James Perry, Mark Speziale, Mark Nespeca, Meredith S. Wright, Martin G. Reese, Francisco M. De La Vega, Joe Azure, Erwin Frise, Charlene Son Rigby, Sandy White, Charlotte A. Hobbs, Sheldon Gilmer, Gail Knight, Albert Oriol, Jerica Lenberg, Shareef A. Nahas, Kate Perofsky, Kyu Kim, Jeanne Carroll, Nicole G. Coufal, Erica Sanford, Kristen Wigby, Jacqueline Weir, Vicki S. Thomson, Louise Fraser, Seka S. Lazare, Yoon H. Shin, Haiying Grunenwald, Richard Lee, David Jones, Duke Tran, Andrew Gross, Patrick Daigle, Anne Case, Marisa Lue, James A. Richardson, John Reynders, Thomas Defay, Kevin P. Hall, Narayanan Veeraraghavan, and Stephen F. Kingsmore

Subjects

Science

Abstract

Rapid diagnosis and implementation of treatments is crucial in many genetic conditions. Here the authors describe Genome-to-Treatment, a virtual disease management system that can achieve a rapid diagnosis by expedited whole genome sequencing in 13.5 hours and provide guidance to clinicians for possible therapies.

Published

2022

3. The Genomic landscape of short tandem repeats across multiple ancestries.

Author

Prashanth Vijayaraghavan, Sergey Batalov, Yan Ding, Erica Sanford, Stephen F Kingsmore, David Dimmock, Charlotte Hobbs, and Matthew Bainbridge

Subjects

Medicine, Science

Abstract

Short Tandem Repeats (STRs) have been found to play a role in a myriad of complex traits and genetic diseases. We examined the variability in the lengths of over 850,000 STR loci in 996 children with suspected genetic disorders and 1,178 parents across six separate ancestral groups: Africans, Europeans, East Asians, Admixed Americans, Non-admixed Americans, and Pacific Islanders. For each STR locus we compared allele length between and within each ancestry group. In relation to Europeans, admixed Americans had the most similar STR lengths with only 623 positions either significantly expanded or contracted, while the divergence was highest in Africans, with 4,933 chromosomal positions contracted or expanded. We also examined probands to identify STR expansions at known pathogenic loci. The genes TCF4, AR, and DMPK showed significant expansions with lengths 250% greater than their various average allele lengths in 49, 162, and 11 individuals respectively. All 49 individuals containing an expansion in TCF4 and six individuals containing an expansion in DMPK presented with allele lengths longer than the known pathogenic length for these genes. Next, we identified individuals with significant expansions in highly conserved loci across all ancestries. Eighty loci in conserved regions met criteria for divergence. Two of these individuals were found to have exonic STR expansions: one in ZBTB4 and the other in SLC9A7, which is associated with X-linked mental retardation. Finally, we used parent-child trios to detect and analyze de novo mutations. In total, we observed 3,219 de novo expansions, where proband allele lengths are greater than twice the longest parental allele length. This work helps lay the foundation for understanding STR lengths genome-wide across ancestries and may help identify new disease genes and novel mechanisms of pathogenicity in known disease genes.

Published

2023

4. Rapid whole genome sequencing impacts care and resource utilization in infants with congenital heart disease

Author

Nathaly M. Sweeney, Shareef A. Nahas, Sh. Chowdhury, Sergey Batalov, Michelle Clark, Sara Caylor, Julie Cakici, John J. Nigro, Yan Ding, Narayanan Veeraraghavan, Charlotte Hobbs, David Dimmock, and Stephen F. Kingsmore

Subjects

Medicine, Genetics, QH426-470

Abstract

Abstract Congenital heart disease (CHD) is the most common congenital anomaly and a major cause of infant morbidity and mortality. While morbidity and mortality are highest in infants with underlying genetic conditions, molecular diagnoses are ascertained in only ~20% of cases using widely adopted genetic tests. Furthermore, cost of care for children and adults with CHD has increased dramatically. Rapid whole genome sequencing (rWGS) of newborns in intensive care units with suspected genetic diseases has been associated with increased rate of diagnosis and a net reduction in cost of care. In this study, we explored whether the clinical utility of rWGS extends to critically ill infants with structural CHD through a retrospective review of rWGS study data obtained from inpatient infants

Published

2021

5. Author Correction: Rapid whole genome sequencing impacts care and resource utilization in infants with congenital heart disease

Author

Nathaly M. Sweeney, Shareef A. Nahas, Shimul Chowdhury, Sergey Batalov, Michelle Clark, Sara Caylor, Julie Cakici, John J. Nigro, Yan Ding, Narayanan Veeraraghavan, Charlotte Hobbs, David Dimmock, and Stephen F. Kingsmore

Subjects

Medicine, Genetics, QH426-470

Published

2021

6. Publisher Correction: Rapid whole genome sequencing impacts care and resource utilization in infants with congenital heart disease

Author

Nathaly M. Sweeney, Shareef A. Nahas, Shimul Chowdhury, Sergey Batalov, Michelle Clark, Sara Caylor, Julie Cakici, John J. Nigro, Yan Ding, Narayanan Veeraraghavan, Charlotte Hobbs, David Dimmock, and Stephen F. Kingsmore

Subjects

Medicine, Genetics, QH426-470

Published

2021

7. High throughput mutagenesis for identification of residues regulating human prostacyclin (hIP) receptor expression and function.

Author

Anke Bill, Elizabeth M Rosethorne, Toby C Kent, Lindsay Fawcett, Lynn Burchell, Michiel T van Diepen, Anthony Marelli, Sergey Batalov, Loren Miraglia, Anthony P Orth, Nicole A Renaud, Steven J Charlton, Martin Gosling, L Alex Gaither, and Paul J Groot-Kormelink

Subjects

Medicine, Science

Abstract

The human prostacyclin receptor (hIP receptor) is a seven-transmembrane G protein-coupled receptor (GPCR) that plays a critical role in vascular smooth muscle relaxation and platelet aggregation. hIP receptor dysfunction has been implicated in numerous cardiovascular abnormalities, including myocardial infarction, hypertension, thrombosis and atherosclerosis. Genomic sequencing has discovered several genetic variations in the PTGIR gene coding for hIP receptor, however, its structure-function relationship has not been sufficiently explored. Here we set out to investigate the applicability of high throughput random mutagenesis to study the structure-function relationship of hIP receptor. While chemical mutagenesis was not suitable to generate a mutagenesis library with sufficient coverage, our data demonstrate error-prone PCR (epPCR) mediated mutagenesis as a valuable method for the unbiased screening of residues regulating hIP receptor function and expression. Here we describe the generation and functional characterization of an epPCR derived mutagenesis library compromising >4000 mutants of the hIP receptor. We introduce next generation sequencing as a useful tool to validate the quality of mutagenesis libraries by providing information about the coverage, mutation rate and mutational bias. We identified 18 mutants of the hIP receptor that were expressed at the cell surface, but demonstrated impaired receptor function. A total of 38 non-synonymous mutations were identified within the coding region of the hIP receptor, mapping to 36 distinct residues, including several mutations previously reported to affect the signaling of the hIP receptor. Thus, our data demonstrates epPCR mediated random mutagenesis as a valuable and practical method to study the structure-function relationship of GPCRs.

Published

2014

8. A genome sequencing system for universal newborn screening, diagnosis, and precision medicine for severe genetic diseases

Author

Stephen F. Kingsmore, Laurie D. Smith, Chris M. Kunard, Matthew Bainbridge, Sergey Batalov, Wendy Benson, Eric Blincow, Sara Caylor, Christina Chambers, Guillermo Del Angel, David P. Dimmock, Yan Ding, Katarzyna Ellsworth, Annette Feigenbaum, Erwin Frise, Robert C. Green, Lucia Guidugli, Kevin P. Hall, Christian Hansen, Charlotte A. Hobbs, Scott D. Kahn, Mark Kiel, Lucita Van Der Kraan, Chad Krilow, Yong H. Kwon, Lakshminarasimha Madhavrao, Jennie Le, Sebastien Lefebvre, Rebecca Mardach, William R. Mowrey, Danny Oh, Mallory J. Owen, George Powley, Gunter Scharer, Seth Shelnutt, Mari Tokita, Shyamal S. Mehtalia, Albert Oriol, Stavros Papadopoulos, James Perry, Edwin Rosales, Erica Sanford, Steve Schwartz, Duke Tran, Martin G. Reese, Meredith Wright, Narayanan Veeraraghavan, Kristen Wigby, Mary J. Willis, Aaron R. Wolen, and Thomas Defay.

Subjects

clinical decision support, UK Biobank, diagnosis, Critical Illness, clinical utility, specificity, rapid whole-genome sequencing, Medical and Health Sciences, Neonatal Screening, Rare Diseases, genetic disease, Clinical Research, Genetics, Humans, Genetic Testing, Precision Medicine, Child, Genetics (clinical), Retrospective Studies, Pediatric, Genetics & Heredity, virtual management guidance, newborn screening, Prevention, diagnostic odyssey, Human Genome, Infant, Newborn, Infant, Perinatal Period - Conditions Originating in Perinatal Period, Biological Sciences, Newborn, sensitivity, gene therapy, orphan drug, Brain Disorders, Good Health and Well Being

Abstract

Newborn screening (NBS) dramatically improves outcomes in severe childhood disorders by treatment before symptom onset. In many genetic diseases, however, outcomes remain poor because NBS has lagged behind drug development. Rapid whole-genome sequencing (rWGS) is attractive for comprehensive NBS because it concomitantly examines almost all genetic diseases and is gaining acceptance for genetic disease diagnosis in ill newborns. We describe prototypic methods for scalable, parentally consented, feedback-informed NBS and diagnosis of genetic diseases by rWGS and virtual, acute management guidance (NBS-rWGS). Using established criteria and the Delphi method, we reviewed 457 genetic diseases for NBS-rWGS, retaining 388 (85%) with effective treatments. Simulated NBS-rWGS in 454,707UK Biobank subjects with 29,865 pathogenic or likely pathogenic variants associated with 388 disorders had a true negative rate (specificity) of 99.7% following root cause analysis. In 2,208 critically ill children with suspected genetic disorders and 2,168 of their parents, simulated NBS-rWGS for 388 disorders identified 104 (87%) of 119 diagnoses previously made by rWGS and 15 findings not previously reported (NBS-rWGS negative predictive value 99.6%, true positive rate [sensitivity] 88.8%). Retrospective NBS-rWGS diagnosed 15 children with disorders that had been undetected by conventional NBS. In 43 of the 104 children, had NBS-rWGS-based interventions been started on day of life 5, the Delphi consensus was that symptoms could have been avoided completely in seven critically ill children, mostly in 21, and partially in 13. We invite groups worldwide to refine these NBS-rWGS conditions and join us to prospectively examine clinical utility and cost effectiveness.

Published

2022

9. Rapid Whole Genome Sequencing for Diagnosis of Single Locus Genetic Diseases in Critically Ill Children

Author

Mallory J. Owen, Sergey Batalov, Katarzyna A. Ellsworth, Meredith Wright, Sylvia Breeding, Kwon Hugh, Stephen F. Kingsmore, and Yan Ding

Published

2023

10. Reclassification of the Etiology of Infant Mortality With Whole-Genome Sequencing

Author

Mallory J. Owen, Meredith S. Wright, Sergey Batalov, Yonghyun Kwon, Yan Ding, Kevin K. Chau, Shimul Chowdhury, Nathaly M. Sweeney, Elizabeth Kiernan, Andrew Richardson, Emily Batton, Rebecca J. Baer, Gretchen Bandoli, Joseph G. Gleeson, Matthew Bainbridge, Christina D. Chambers, and Stephen F. Kingsmore

Subjects

General Medicine

Abstract

ImportanceUnderstanding the causes of infant mortality shapes public health, surveillance, and research investments. However, the association of single-locus (mendelian) genetic diseases with infant mortality is poorly understood.ObjectiveTo determine the association of genetic diseases with infant mortality.Design, Setting, and ParticipantsThis cohort study was conducted at a large pediatric hospital system in San Diego County (California) and included 546 infants (112 infant deaths [20.5%] and 434 infants [79.5%] with acute illness who survived; age, 0 to 1 year) who underwent diagnostic whole-genome sequencing (WGS) between January 2015 and December 2020. Data analysis was conducted between 2015 and 2022.ExposureInfants underwent WGS either premortem or postmortem with semiautomated phenotyping and diagnostic interpretation.Main Outcomes and MeasuresProportion of infant deaths associated with single-locus genetic diseases.ResultsAmong 112 infant deaths (54 girls [48.2%]; 8 [7.1%] African American or Black, 1 [0.9%] American Indian or Alaska Native, 8 [7.1%] Asian, 48 [42.9%] Hispanic, 1 [0.9%] Native Hawaiian or Pacific Islander, and 34 [30.4%] White infants) in San Diego County between 2015 and 2020, single-locus genetic diseases were the most common identifiable cause of infant mortality, with 47 genetic diseases identified in 46 infants (41%). Thirty-nine (83%) of these diseases had been previously reported to be associated with childhood mortality. Twenty-eight death certificates (62%) for 45 of the 46 infants did not mention a genetic etiology. Treatments that can improve outcomes were available for 14 (30%) of the genetic diseases. In 5 of 7 infants in whom genetic diseases were identified postmortem, death might have been avoided had rapid, diagnostic WGS been performed at time of symptom onset or regional intensive care unit admission.Conclusions and RelevanceIn this cohort study of 112 infant deaths, the association of genetic diseases with infant mortality was higher than previously recognized. Strategies to increase neonatal diagnosis of genetic diseases and immediately implement treatment may decrease infant mortality. Additional study is required to explore the generalizability of these findings and measure reduction in infant mortality.

Published

2023

11. Rapid Sequencing-Based Diagnosis of Thiamine Metabolism Dysfunction Syndrome

Author

Anna-Kaisa Niemi, Kevin Hall, Meredith S. Wright, Mark Speziale, Louise Fraser, Jerica Lenberg, Shimul Chowdhury, Tim K McPhail, Sergey Batalov, Luca Van Der Kraan, Kevin K Chau, David Dimmock, Vicki S Thomson, Christian Hansen, Yan Ding, Mark Nespeca, Shyamal S Mehtalia, Sheldon Gilmer, Stephen F. Kingsmore, Mallory J Owen, Zhanyang Zhu, Gail Knight, Chris M Kunard, Charlotte A. Hobbs, Jacqueline Weir, John Reynders, Narayanan Veeraraghavan, Bryan R. Lajoie, Sebastien Lefebvre, Shareef Nahas, and Thomas Defay

Subjects

Whole genome sequencing, Infantile encephalopathy, 2019-20 coronavirus outbreak, business.industry, Thiamine Metabolism, General Medicine, Bioinformatics, Genome, Article, Neurologic injury, X ray computed, Medicine, business, Genetic diagnosis

Abstract

Speedy Genetic Diagnosis Infantile encephalopathy is associated with approximately 1500 genetic diseases. Without prompt treatment, permanent neurologic injury or death may occur. Here, the genome ...

Published

2021

12. Author Correction: Rapid whole genome sequencing impacts care and resource utilization in infants with congenital heart disease

Author

Narayanan Veeraraghavan, Michelle M. Clark, John J. Nigro, Charlotte A. Hobbs, Sara A. Caylor, David Dimmock, Nathaly M. Sweeney, Shareef Nahas, Yan Ding, Julie A. Cakici, Sergey Batalov, Stephen F. Kingsmore, and Shimul Chowdhury

Subjects

Whole genome sequencing, Heart disease, business.industry, MEDLINE, Computational biology, QH426-470, Health care economics, medicine.disease, Congenital heart defects, Genetics, medicine, Medicine, business, Author Correction, Molecular Biology, Medical genomics, Genetics (clinical), Resource utilization

Abstract

Congenital heart disease (CHD) is the most common congenital anomaly and a major cause of infant morbidity and mortality. While morbidity and mortality are highest in infants with underlying genetic conditions, molecular diagnoses are ascertained in only ~20% of cases using widely adopted genetic tests. Furthermore, cost of care for children and adults with CHD has increased dramatically. Rapid whole genome sequencing (rWGS) of newborns in intensive care units with suspected genetic diseases has been associated with increased rate of diagnosis and a net reduction in cost of care. In this study, we explored whether the clinical utility of rWGS extends to critically ill infants with structural CHD through a retrospective review of rWGS study data obtained from inpatient infants 1 year with structural CHD at a regional children's hospital. rWGS diagnosed genetic disease in 46% of the enrolled infants. Moreover, genetic disease was identified five times more frequently with rWGS than microarray ± gene panel testing in 21 of these infants (rWGS diagnosed 43% versus 10% with microarray ± gene panels, p = 0.02). Molecular diagnoses ranged from syndromes affecting multiple organ systems to disorders limited to the cardiovascular system. The average daily hospital spending was lower in the time period post blood collection for rWGS compared to prior (p = 0.003) and further decreased after rWGS results (p = 0.000). The cost was not prohibitive to rWGS implementation in the care of this cohort of infants. rWGS provided timely actionable information that impacted care and there was evidence of decreased hospital spending around rWGS implementation.

Published

2021

13. An RCT of Rapid Genomic Sequencing among Seriously Ill Infants Results in High Clinical Utility, Changes in Management, and Low Perceived Harm

Author

David Dimmock, Cinnamon S. Bloss, Yan Ding, Kiely N. James, Katarzyna A. Ellsworth, Narayanan Veeraraghavan, Matthew N. Bainbridge, Amy S. Kimball, Jaime Barea, Christina Clarke, Jerica Lenberg, Shareef Nahas, Shimul Chowdhury, Erica Sanford, Patrick Mulrooney, Nathaly M. Sweeney, Sergey Batalov, Lauge Farnaes, Jennie Le, Cynthia Cheung, Mary Gaughran, Leila Schwanemann, Daniken Orendain, Maria Ortiz-Arechiga, Charlotte A. Hobbs, Marva Evans, Kelly Watkins, Marilyn C. Jones, Joshua J.A. Braun, Meredith S. Wright, Terence C. Wong, Carlos Diaz, Mari Tokita, Miguel Del Campo, Brian Lane, Stephen F. Kingsmore, Christian Hansen, Lisa Salz, Michelle M. Clark, Nicole G. Coufal, Casey Cohenmeyer, Joe Gleeson, Seema Rego, Kristen Wigby, Jennifer Friedman, Zaira Bezares, Mark Speziale, Sara A. Caylor, Lance Prince, Richard S. Song, Jose Honold, Albert Oriol, Catherine Yamada, Annette Feigenbaum, Lucitia Van Der Kraan, Sandra Leibel, Denise Suttner, Dana Mashburn, Laurel Moyer, Julie A. Cakici, Lynne M. Bird, Charles Sauer, Daeheon Oh, Iris Reyes, Gail Knight, Michele Feddock, and Jeanne Carroll

Subjects

0301 basic medicine, Male, medicine.medical_specialty, Neonatal intensive care unit, Time Factors, Critical Illness, Clinical Decision-Making, Logistic regression, Article, law.invention, 03 medical and health sciences, 0302 clinical medicine, Randomized controlled trial, law, 030225 pediatrics, Intensive care, Internal medicine, Intensive Care Units, Neonatal, Genetics, Medicine, Humans, Genetic Testing, Prospective Studies, Genetics (clinical), Pediatric intensive care unit, Whole Genome Sequencing, business.industry, Genome, Human, Genetic Diseases, Inborn, Infant, Newborn, Chromosome Mapping, Disease Management, Infant, Odds ratio, Distress, 030104 developmental biology, Logistic Models, Etiology, Female, sense organs, business

Abstract

The second Newborn Sequencing in Genomic Medicine and Public Health (NSIGHT2) study was a randomized, controlled trial of rapid whole-genome sequencing (rWGS) or rapid whole-exome sequencing (rWES) in infants with diseases of unknown etiology in intensive care units (ICUs). Gravely ill infants were not randomized and received ultra-rapid whole-genome sequencing (urWGS). Herein we report results of clinician surveys of the clinical utility of rapid genomic sequencing (RGS). The primary end-point-clinician perception that RGS was useful- was met for 154 (77%) of 201 infants. Both positive and negative tests were rated as having clinical utility (42 of 45 [93%] and 112 of 156 [72%], respectively). Physicians reported that RGS changed clinical management in 57 (28%) infants, particularly in those receiving urWGS (p = 0.0001) and positive tests (p < 0.00001). Outcomes of 32 (15%) infants were perceived to be changed by RGS. Positive tests changed outcomes more frequently than negative tests (p < 0.00001). In logistic regression models, the likelihood that RGS was perceived as useful increased 6.7-fold when associated with changes in management (95% CI 1.8-43.3). Changes in management were 10.1-fold more likely when results were positive (95% CI 4.7-22.4) and turnaround time was shorter (odds ratio 0.92, 95% CI 0.85-0.99). RGS seldom led to clinician-perceived confusion or distress among families (6 of 207 [3%]). In summary, clinicians perceived high clinical utility and low likelihood of harm with first-tier RGS of infants in ICUs with diseases of unknown etiology. RGS was perceived as beneficial irrespective of whether results were positive or negative.

Published

2020

14. A Randomized, Controlled Trial of the Analytic and Diagnostic Performance of Singleton and Trio, Rapid Genome and Exome Sequencing in Ill Infants

Author

David Dimmock, Dorjee Tamang, Sarah White, Peter Schols, Michelle M. Clark, Zaira Bezares, Richard S. Song, Sandra Leibel, Denise Suttner, Jennie Le, Charlotte A. Hobbs, Casey Cohenmeyer, Katarzyna A. Ellsworth, Brian Lane, Amber Hildreth, Lauge Farnaes, Kelly Watkins, Kiely N. James, Terence C. Wong, Cinnamon S. Bloss, Nicole G. Coufal, Laura Puckett, Mari Tokita, Lance Prince, Amy S. Kimball, Narayanan Veeraraghavan, Shareef Nahas, Cyrielle Kint, Yan Ding, Paulina Ordonez, Jaime Barea, Erica Sanford, Kristen Wigby, Daniken Orendain, Maria Ortiz-Arechiga, Meredith S. Wright, Dana Mashburn, Sara A. Caylor, Nathaly M. Sweeney, Joshua J.A. Braun, Christina Clarke, Audra Wise, Lisa Salz, Charles Sauer, Jenni Friedman, George Chiang, Jerica Lenberg, Mark Speziale, Laurel Moyer, Michele Feddock, Jeanne Carroll, Patrick Mulrooney, Raymond Hovey, Stephen F. Kingsmore, Marva Evans, Sergey Batalov, Albert Oriol, Joe Gleeson, Jose Honold, Carlos Diaz, Mary Gaughran, Julie A. Cakici, Crystal Le, Catherine Yamada, Shimul Chowdhury, Gail Knight, Matthew N. Bainbridge, Lucitia Van Der Kraan, Daeheon Oh, and Iris Reyes

Subjects

0301 basic medicine, ultra-rapid whole-genome sequencing, Pediatrics, medicine.medical_specialty, diagnosis, precision medicine, RCIGM Investigators, Clinical Trials and Supportive Activities, 030105 genetics & heredity, Genome, intensive care unit, Medical and Health Sciences, Article, law.invention, 03 medical and health sciences, Randomized controlled trial, law, genetic disease, Clinical Research, Exome Sequencing, medicine, Genetics, Humans, Genetic Testing, whole-exome sequencing, Genetics (clinical), Exome sequencing, Whole genome sequencing, Pediatric, Genetics & Heredity, Whole Genome Sequencing, business.industry, Singleton, Human Genome, Infant, Newborn, Infant, Biological Sciences, Precision medicine, Newborn, Intensive care unit, 030104 developmental biology, genomic medicine, Good Health and Well Being, whole-genome sequencing, Etiology, business

Abstract

The second Newborn Sequencing in Genomic Medicine and Public Health study was a randomized, controlled trial of the effectiveness of rapid whole-genome or -exome sequencing (rWGS or rWES, respectively) in seriously ill infants with diseases of unknown etiology. Here we report comparisons of analytic and diagnostic performance. Of 1,248 ill inpatient infants, 578 (46%) had diseases of unknown etiology. 213 infants (37% of those eligible) were enrolled within 96h of admission. 24 infants (11%) were very ill and received ultra-rapid whole-genome sequencing (urWGS). The remaining infants were randomized, 95 to rWES and 94 to rWGS. The analytic performance of rWGS was superior to rWES, including variants likely to affect protein function, and ClinVar pathogenic/likely pathogenic variants (p < 0.0001). The diagnostic performance of rWGS and rWES were similar (18 diagnoses in 94 infants [19%] versus 19 diagnoses in 95 infants [20%], respectively), as was time to result (median 11.0 versus 11.2days, respectively). However, the proportion diagnosed by urWGS (11 of 24 [46%]) was higher than rWES/rWGS (p = 0.004) and time to result was less (median 4.6days, p < 0.0001). The incremental diagnostic yield of reflexing to trio after negative proband analysis was 0.7% (1 of 147). In conclusion, rapid genomic sequencing can be performed as a first-tier diagnostic test in inpatient infants. urWGS had the shortest time to result, which was important in unstable infants, and those in whom a genetic diagnosis was likely to impact immediate management. Further comparison of urWGS and rWES is warranted because genomic technologies and knowledge of variant pathogenicity are evolving rapidly.

Published

2019

15. Publisher Correction: Rapid whole genome sequencing impacts care and resource utilization in infants with congenital heart disease

Author

Sara A. Caylor, Shareef Nahas, David Dimmock, John J. Nigro, Shimul Chowdhury, Stephen F. Kingsmore, Michelle M. Clark, Narayanan Veeraraghavan, Julie A. Cakici, Yan Ding, Nathaly M. Sweeney, Sergey Batalov, and Charlotte A. Hobbs

Subjects

Whole genome sequencing, Heart disease, Computational biology, Biology, Health care economics, QH426-470, medicine.disease, Publisher Correction, Congenital heart defects, medicine, Genetics, Medicine, Molecular Biology, Medical genomics, Genetics (clinical), Resource utilization

Published

2021

16. Diagnosis of genetic diseases in seriously ill children by rapid whole-genome sequencing and automated phenotyping and interpretation

Author

Terence C. Wong, Marie L. Janes, John Reynders, Martin G. Reese, Brett Williams, Patrick Mulrooney, Sergey Batalov, Kristen Wigby, Brandon Camp, Lauge Farnaes, Joshua J.A. Braun, Meredith S. Wright, Narayanan Veeraraghavan, Jeremy Gore, Shareef Nahas, David Dimmock, Sheldon Gilmer, Lisa Salz, Albert Oriol, Mari Tokita, Kejia Lin, Thomas Defay, Erica Sanford, Catherine Yamada, Nathaly M. Sweeney, Stephen F. Kingsmore, Yan Ding, Christina Clarke, Laura Puckett, Katarzyna A. Ellsworth, Richard Gain, Shauna George, Luca Van Der Kraan, Margaret Bray, Mary Gaughran, Curtis Beebe, Alison Frith, Kevin Hall, Kyle McBride, Amber Hildreth, Michelle M. Clark, Haiying Li Grunenwald, Julie Ryu, Cyrielle Kint, Kelly Watkins, Mitchell Creed, Jennifer Friedman, Shimul Chowdhury, Paul D. McDonagh, Zia Rady, Peter Schols, Joseph G. Gleeson, Julie A. Cakici, Lawrence Stewart, Raymond Hovey, Jeanne Carroll, Matthew N. Bainbridge, Daeheon Oh, Calum Yacoubian, Sara A. Caylor, and Sarah White

Subjects

0301 basic medicine, medicine.medical_specialty, 030105 genetics & heredity, Phenome, Genome, DNA sequencing, Diabetic Ketoacidosis, 03 medical and health sciences, Intensive care, medicine, Electronic Health Records, Humans, Medical diagnosis, Intensive care medicine, Natural Language Processing, Retrospective Studies, Whole genome sequencing, business.industry, General Medicine, Genomics, Intensive Care Units, 030104 developmental biology, DECIPHER, Female, Precision and recall, business

Abstract

By informing timely targeted treatments, rapid whole-genome sequencing can improve the outcomes of seriously ill children with genetic diseases, particularly infants in neonatal and pediatric intensive care units (ICUs). The need for highly qualified professionals to decipher results, however, precludes widespread implementation. We describe a platform for population-scale, provisional diagnosis of genetic diseases with automated phenotyping and interpretation. Genome sequencing was expedited by bead-based genome library preparation directly from blood samples and sequencing of paired 100-nt reads in 15.5 hours. Clinical natural language processing (CNLP) automatically extracted children’s deep phenomes from electronic health records with 80% precision and 93% recall. In 101 children with 105 genetic diseases, a mean of 4.3 CNLP-extracted phenotypic features matched the expected phenotypic features of those diseases, compared with a match of 0.9 phenotypic features used in manual interpretation. We automated provisional diagnosis by combining the ranking of the similarity of a patient’s CNLP phenome with respect to the expected phenotypic features of all genetic diseases, together with the ranking of the pathogenicity of all of the patient’s genomic variants. Automated, retrospective diagnoses concurred well with expert manual interpretation (97% recall and 99% precision in 95 children with 97 genetic diseases). Prospectively, our platform correctly diagnosed three of seven seriously ill ICU infants (100% precision and recall) with a mean time saving of 22:19 hours. In each case, the diagnosis affected treatment. Genome sequencing with automated phenotyping and interpretation in a median of 20:10 hours may increase adoption in ICUs and, thereby, timely implementation of precise treatments.

Published

2018

17. Rapid whole-genome sequencing identifies a novel homozygous

Author

Amber, Hildreth, Kristen, Wigby, Shimul, Chowdhury, Shareef, Nahas, Jaime, Barea, Paulina, Ordonez, Sergey, Batalov, David, Dimmock, and Stephen, Kingsmore

Subjects

Male, congenital, hereditary, and neonatal diseases and abnormalities, foam cells with lamellar inclusion bodies, generalized neonatal hypotonia, Niemann-Pick C1 Protein, hemic and lymphatic diseases, Humans, abnormal cholesterol homeostasis, Niemann-Pick Diseases, clinodactyly of the 5th finger, Cholestasis, Genome, Membrane Glycoproteins, Liver Diseases, Homozygote, Intracellular Signaling Peptides and Proteins, nutritional and metabolic diseases, Infant, Niemann-Pick Disease, Type C, prolonged neonatal jaundice, Sequence Analysis, DNA, Cholesterol, Mutation, hepatosplenomegaly, Carrier Proteins, Rapid Communication

Abstract

Niemann–Pick type C disease (NPC; OMIM #257220) is an inborn error of intracellular cholesterol trafficking. It is an autosomal recessive disorder caused predominantly by mutations in NPC1. Although characterized as a progressive neurological disorder, it can also cause cholestasis and liver dysfunction because of intrahepatocyte lipid accumulation. We report a 7-wk-old infant who was admitted with neonatal cholestasis, and who was diagnosed with a novel homozygous stop-gain variant in NPC1 by rapid whole-genome sequencing (WGS). WGS results were obtained 16 d before return of the standard clinical genetic test results and prompted initiation of targeted therapy.

Published

2017

18. Rapid whole-genome sequencing identifies a novel homozygous NPC1 variant associated with Niemann–Pick type C1 disease in a 7-week-old male with cholestasis

Author

Jaime Barea, Sergey Batalov, Amber Hildreth, Shimul Chowdhury, Stephen F. Kingsmore, Shareef Nahas, David Dimmock, Paulina Ordonez, and Kristen Wigby

Subjects

0301 basic medicine, Whole genome sequencing, congenital, hereditary, and neonatal diseases and abnormalities, business.industry, medicine.medical_treatment, Hepatosplenomegaly, nutritional and metabolic diseases, General Medicine, Disease, Neurological disorder, medicine.disease, Bioinformatics, 3. Good health, Targeted therapy, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, Cholestasis, Immunology, Medicine, Neonatal cholestasis, NPC1, medicine.symptom, business, 030217 neurology & neurosurgery

Abstract

Niemann–Pick type C disease (NPC; OMIM #257220) is an inborn error of intracellular cholesterol trafficking. It is an autosomal recessive disorder caused predominantly by mutations in NPC1. Although characterized as a progressive neurological disorder, it can also cause cholestasis and liver dysfunction because of intrahepatocyte lipid accumulation. We report a 7-wk-old infant who was admitted with neonatal cholestasis, and who was diagnosed with a novel homozygous stop-gain variant in NPC1 by rapid whole-genome sequencing (WGS). WGS results were obtained 16 d before return of the standard clinical genetic test results and prompted initiation of targeted therapy.

Published

2017

19. High Throughput Mutagenesis for Identification of Residues Regulating Human Prostacyclin (hIP) Receptor Expression and Function

Author

Michiel T. van Diepen, Paul J. Groot-Kormelink, Lynn Burchell, Anthony Marelli, L. Alex Gaither, Anke Bill, Anthony P. Orth, Steven J. Charlton, Elizabeth M. Rosethorne, Sergey Batalov, Loren Miraglia, Toby C. Kent, Lindsay Fawcett, Nicole A. Renaud, and Martin Gosling

Subjects

Receptor expression, Receptors, Prostaglandin, Cardiology, Mutagenesis (molecular biology technique), lcsh:Medicine, Hydroxylamine, Biology, medicine.disease_cause, Receptors, Epoprostenol, Biochemistry, Polymerase Chain Reaction, Cell Signaling, Mutation Rate, Molecular Cell Biology, medicine, Genetics, Medicine and Health Sciences, Coding region, Humans, Membrane Receptor Signaling, Computer Simulation, Amino Acids, Receptor, lcsh:Science, Prostacyclin receptor, G protein-coupled receptor, Mutation, Multidisciplinary, Point mutation, lcsh:R, Biology and Life Sciences, Proteins, High-Throughput Nucleotide Sequencing, Cell Biology, G-Protein Signaling, HEK293 Cells, Mutagenesis, Cellular Neuroscience, lcsh:Q, Research Article, Signal Transduction, Neuroscience

Abstract

The human prostacyclin receptor (hIP receptor) is a seven-transmembrane G protein-coupled receptor (GPCR) that plays a critical role in vascular smooth muscle relaxation and platelet aggregation. hIP receptor dysfunction has been implicated in numerous cardiovascular abnormalities, including myocardial infarction, hypertension, thrombosis and atherosclerosis. Genomic sequencing has discovered several genetic variations in the PTGIR gene coding for hIP receptor, however, its structure-function relationship has not been sufficiently explored. Here we set out to investigate the applicability of high throughput random mutagenesis to study the structure-function relationship of hIP receptor. While chemical mutagenesis was not suitable to generate a mutagenesis library with sufficient coverage, our data demonstrate error-prone PCR (epPCR) mediated mutagenesis as a valuable method for the unbiased screening of residues regulating hIP receptor function and expression. Here we describe the generation and functional characterization of an epPCR derived mutagenesis library compromising >4000 mutants of the hIP receptor. We introduce next generation sequencing as a useful tool to validate the quality of mutagenesis libraries by providing information about the coverage, mutation rate and mutational bias. We identified 18 mutants of the hIP receptor that were expressed at the cell surface, but demonstrated impaired receptor function. A total of 38 non-synonymous mutations were identified within the coding region of the hIP receptor, mapping to 36 distinct residues, including several mutations previously reported to affect the signaling of the hIP receptor. Thus, our data demonstrates epPCR mediated random mutagenesis as a valuable and practical method to study the structure-function relationship of GPCRs.

Published

2014

20. Systems biology and malaria

Author

Winzeler, E. A., Le Roch, K. G., Zhou, Y., Blair, P. L., Grainger, M., Kathleen Moch, J., David Haynes, J., La Vega, P., Holder, A. A., Sergey Batalov, and Carucci, D. J.