Kate G Ackerman

Publications (10)64.2 Total impact

• Article: Congenital diaphragmatic hernia candidate genes derived from embryonic transcriptomes.

  Meaghan K Russell, Mauro Longoni, Julie Wells, Faouzi I Maalouf, Adam A Tracy, Maria Loscertales, Kate G Ackerman, Barbara R Pober, Kasper Lage, Carol J Bult, Patricia K Donahoe
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  ABSTRACT: Congenital diaphragmatic hernia (CDH) is a common (1 in 3,000 live births) major congenital malformation that results in significant morbidity and mortality. The discovery of CDH loci using standard genetic approaches has been hindered by its genetic heterogeneity. We hypothesized that gene expression profiling of developing embryonic diaphragms would help identify genes likely to be associated with diaphragm defects. We generated a time series of whole-transcriptome expression profiles from laser captured embryonic mouse diaphragms at embryonic day (E)11.5 and E12.5 when experimental perturbations lead to CDH phenotypes, and E16.5 when the diaphragm is fully formed. Gene sets defining biologically relevant pathways and temporal expression trends were identified by using a series of bioinformatic algorithms. These developmental sets were then compared with a manually curated list of genes previously shown to cause diaphragm defects in humans and in mouse models. Our integrative filtering strategy identified 27 candidates for CDH. We examined the diaphragms of knockout mice for one of the candidate genes, pre-B-cell leukemia transcription factor 1 (Pbx1), and identified a range of previously undetected diaphragmatic defects. Our study demonstrates the utility of genetic characterization of normal development as an integral part of a disease gene identification and prioritization strategy for CDH, an approach that can be extended to other diseases and developmental anomalies.
  Proceedings of the National Academy of Sciences 02/2012; 109(8):2978-83. · 9.68 Impact Factor
• Article: The naive airway hyperresponsiveness of the A/J mouse is Kit-mediated.

  Emily Cozzi, Kate G Ackerman, Anders Lundequist, Jeffrey M Drazen, Joshua A Boyce, David R Beier
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  ABSTRACT: There is a wide variation among humans and mice in airway hyperresponsiveness (AHR) in the absence of allergen sensitization, i.e., naïve AHR. Because mast cell (MC) activation is thought to mediate AHR in atopic asthmatic subjects, we asked whether MCs mediate naïve AHR in A/J mice. We generated an A/J congenic strain lacking c-Kit by introgression of the Wv mutation, which resulted in the elimination of MCs and the abrogation of naïve AHR. Imatinib, which disrupts Kit signaling, also abrogated AHR in A/J mice. Remarkably, introduction of the Vga9 Mitf mutation into the A/J background resulted in the ablation of MCs but did not ameliorate AHR. These results indicate that c-Kit is required for development of AHR in an MC-independent fashion.
  Proceedings of the National Academy of Sciences 08/2011; 108(31):12787-92. · 9.68 Impact Factor
• Article: Characterization of the chromosome 1q41q42.12 region, and the candidate gene DISP1, in patients with CDH.

  Sibel Kantarci, Kate G Ackerman, Meaghan K Russell, Mauro Longoni, Carrie Sougnez, Kristin M Noonan, Eli Hatchwell, Xiaoyun Zhang, Rafael Pieretti Vanmarcke, Kwame Anyane-Yeboa, Paul Dickman, Jay Wilson, Patricia K Donahoe, Barbara R Pober
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  ABSTRACT: Cytogenetic and molecular cytogenetic studies demonstrate association between congenital diaphragmatic hernia (CDH) and chromosome 1q41q42 deletions. In this study, we screened a large CDH cohort (N=179) for microdeletions in this interval by the multiplex ligation-dependent probe amplification (MLPA) technique, and also sequenced two candidate genes located therein, dispatched 1 (DISP1) and homo sapiens H2.0-like homeobox (HLX). MLPA analysis verified deletions of this region in two cases, an unreported patient with a 46,XY,del(1)(q41q42.13) karyotype and a previously reported patient with a Fryns syndrome phenotype [Kantarci et al., 2006]. HLX sequencing showed a novel but maternally inherited single nucleotide variant (c.27C>G) in a patient with isolated CDH, while DISP1 sequencing revealed a mosaic de novo heterozygous substitution (c.4412C>G; p.Ala1471Gly) in a male with a left-sided Bochdalek hernia plus multiple other anomalies. Pyrosequencing demonstrated the mutant allele was present in 43%, 12%, and 4.5% of the patient's lymphoblastoid, peripheral blood lymphocytes, and saliva cells, respectively. We examined Disp1 expression at day E11.5 of mouse diaphragm formation and confirmed its presence in the pleuroperitoneal fold, as well as the nearby lung which also expresses Sonic hedgehog (Shh). Our report describes the first de novo DISP1 point mutation in a patient with complex CDH. Combining this finding with Disp1 embryonic mouse diaphragm and lung tissue expression, as well as previously reported human chromosome 1q41q42 aberrations in patients with CDH, suggests that DISP1 may warrant further consideration as a CDH candidate gene.
  American Journal of Medical Genetics Part A 10/2010; 152A(10):2493-504. · 2.39 Impact Factor
• Article: Fog2 is critical for cardiac function and maintenance of coronary vasculature in the adult mouse heart.

  Bin Zhou, Qing Ma, Sek Won Kong, Yongwu Hu, Patrick H Campbell, Francis X McGowan, Kate G Ackerman, Bingruo Wu, Sergei G Tevosian, William T Pu
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  ABSTRACT: Aberrant transcriptional regulation contributes to the pathogenesis of both congenital and adult forms of heart disease. While the transcriptional regulator friend of Gata 2 (FOG2) is known to be essential for heart morphogenesis and coronary development, its tissue-specific function has not been previously investigated. Additionally, little is known about the role of FOG2 in the adult heart. Here we used spatiotemporally regulated inactivation of Fog2 to delineate its function in both the embryonic and adult mouse heart. Early cardiomyocyte- restricted loss of Fog2 recapitulated the cardiac and coronary defects of the Fog2 germline murine knockouts. Later cardiomyocyte-restricted loss of Fog2 (Fog2MC) did not result in defects in cardiac structure or coronary vessel formation. However, Fog2MC adult mice had severely depressed ventricular function and died at 8-14 weeks. Fog2MC adult hearts displayed a paucity of coronary vessels, associated with myocardial hypoxia, increased cardiomyocyte apoptosis, and cardiac fibrosis. Induced inactivation of Fog2 in the adult mouse heart resulted in similar phenotypes, as did ablation of the FOG2 interaction with the transcription factor GATA4. Loss of the FOG2 or FOG2-GATA4 interaction altered the expression of a panel of angiogenesis-related genes. Collectively, our data indicate that FOG2 regulates adult heart function and coronary angiogenesis.
  The Journal of clinical investigation 06/2009; 119(6):1462-76. · 15.39 Impact Factor
• Article: Congenital diaphragmatic hernia and pulmonary hypoplasia: new insights from developmental biology and genetics.

  Kate G Ackerman, Barbara R Pober
  American Journal of Medical Genetics Part C Seminars in Medical Genetics 06/2007; 145C(2):105-8. · 4.06 Impact Factor
• Article: Development of the diaphragm and genetic mouse models of diaphragmatic defects.

  Kate G Ackerman, John J Greer
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  ABSTRACT: Improving our understanding of diaphragmatic development is essential to making progress in defining the pathogenesis and genetic etiologies of congenital diaphragmatic defects in humans. As mouse genetic technology has given us new tools to manipulate and observe development, a number of mouse models have recently emerged that provide valuable insight to this field. In this article, we review our current understanding of diaphragmatic embryogenesis including the origin of diaphragmatic tissue. We use rodent models to review the muscularization of the diaphragm and review selected genetic models of abnormal muscularization. We also review models of posterior diaphragmatic defects and discuss evidence for the pleuroperitoneal fold (PPF) tissue contributing to the diaphragm. Finally, we discuss models of anterior and central hernias. It may be simplistic to subdivide this review based on anatomic regions of the diaphragm, as evidence is emerging that defects in different regions of the diaphragm in humans and in mice may be etiologically related. However, at this time we do not have enough knowledge to make more mechanistic or genetic classifications though with time, genetic progress in the field of diaphragm development will allow us to do this.
  American Journal of Medical Genetics Part C Seminars in Medical Genetics 06/2007; 145C(2):109-16. · 4.06 Impact Factor
• Article: Gata4 is necessary for normal pulmonary lobar development.

  Kate G Ackerman, Jianlong Wang, Liqing Luo, Yuko Fujiwara, Stuart H Orkin, David R Beier
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  ABSTRACT: Mutations of Fog2 in mice result in a phenotype that includes pulmonary lobar defects. To determine whether formation of the accessory lobe bronchus is mediated by a Gata family cofactor, we evaluated embryonic lungs from mice carrying missense mutations that cause loss of FOG-GATA protein interaction. Lungs from embryos carrying a missense mutation in Gata6 were structurally normal, while lungs from embryos carrying mutations of either Gata4 or of both Gata4 and Gata6 had a structural phenotype that matched the Fog2 mutant phenotype. Expression analysis showed that Gata4 and Fog2 are expressed in the ventral and medial pulmonary mesenchyme during secondary budding. Although Gata4 has not previously been suspected as playing a role in lung development, we have found that a Fog2-Gata4 interaction is critical for the development of normal pulmonary lobar structure, and this phenotype is not influenced by the additional loss of Gata6 interaction. Fog2 and Gata4 in the early pulmonary mesenchyme participate in patterning the secondary bronchus of the accessory lobe.
  American Journal of Respiratory Cell and Molecular Biology 05/2007; 36(4):391-7. · 5.13 Impact Factor
• Article: Infants with Bochdalek diaphragmatic hernia: sibling precurrence and monozygotic twin discordance in a hospital-based malformation surveillance program.

  Barbara R Pober, Angela Lin, Meaghan Russell, Kate G Ackerman, Sharmila Chakravorty, Bernarda Strauss, Marie Noel Westgate, Jay Wilson, Patricia K Donahoe, Lewis B Holmes
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  ABSTRACT: Congenital diaphragmatic hernia (CDH) is a common and often devastating birth defect. In order to learn more about possible genetic causes, we reviewed and classified 203 cases of the Bochdalek hernia type identified through the Brigham and Women's Hospital (BWH) Active Malformation Surveillance Program over a 28-year period. Phenotypically, 55% of the cases had isolated CDH, and 45% had complex CDH defined as CDH in association with additional major malformations or as part of a syndrome. When classified according to likely etiology, 17% had a Recognized Genetic etiology for their CDH, while the remaining 83% had No Apparent Genetic etiology. Detailed analysis using this largest cohort of consecutively collected cases of CDH showed low precurrence among siblings. Additionally, there was no concordance for CDH among five monozygotic twin pairs. These findings, in conjunction with previous reports of de novo dominant mutations in patients with CDH, suggest that new mutations may be an important mechanism responsible for CDH. The twin data also raise the possibility that epigenetic abnormalities contribute to the development of CDH.
  American Journal of Medical Genetics Part A 11/2005; 138A(2):81-8. · 2.39 Impact Factor
• Source

  Available from: David R Beier

  Article: Fog2 is required for normal diaphragm and lung development in mice and humans.

  Kate G Ackerman, Bruce J Herron, Sara O Vargas, Hailu Huang, Sergei G Tevosian, Lazaros Kochilas, Cherie Rao, Barbara R Pober, Randal P Babiuk, Jonathan A Epstein, John J Greer, David R Beier
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  ABSTRACT: Congenital diaphragmatic hernia and other congenital diaphragmatic defects are associated with significant mortality and morbidity in neonates; however, the molecular basis of these developmental anomalies is unknown. In an analysis of E18.5 embryos derived from mice treated with N-ethyl-N-nitrosourea, we identified a mutation that causes pulmonary hypoplasia and abnormal diaphragmatic development. Fog2 (Zfpm2) maps within the recombinant interval carrying the N-ethyl-N-nitrosourea-induced mutation, and DNA sequencing of Fog2 identified a mutation in a splice donor site that generates an abnormal transcript encoding a truncated protein. Human autopsy cases with diaphragmatic defect and pulmonary hypoplasia were evaluated for mutations in FOG2. Sequence analysis revealed a de novo mutation resulting in a premature stop codon in a child who died on the first day of life secondary to severe bilateral pulmonary hypoplasia and an abnormally muscularized diaphragm. Using a phenotype-driven approach, we have established that Fog2 is required for normal diaphragm and lung development, a role that has not been previously appreciated. FOG2 is the first gene implicated in the pathogenesis of nonsyndromic human congenital diaphragmatic defects, and its necessity for pulmonary development validates the hypothesis that neonates with congenital diaphragmatic hernia may also have primary pulmonary developmental abnormalities.
  PLoS Genetics 08/2005; 1(1):58-65. · 8.69 Impact Factor
• Article: Interacting genetic loci cause airway hyperresponsiveness.

  Kate G Ackerman, Hailu Huang, Hartmut Grasemann, Chris Puma, Jonathan B Singer, Annie E Hill, Eric Lander, Joseph H Nadeau, Gary A Churchill, Jeffrey M Drazen, David R Beier
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  ABSTRACT: Airway hyperresponsiveness (AHR) is a key physiological component of asthma, and the genetic basis of this complex trait has remained elusive. We created recombinant congenic mice with increased naive AHR by serially backcrossing A/J mice (which have elevated naive AHR) with C57BL/6J mice and selecting for mice with an elevated naive AHR phenotype. The seventh backcross-generation hyperresponsive mice retained A/J loci in three regions. Quantitative trait linkage (QTL) analysis of 123 unselected N8 progeny demonstrated that the AHR phenotype was not associated with any single locus but was significantly associated with an interaction of loci on chromosomes 2 and 6. These findings were confirmed in an independent analysis of chromosome substitution strain mice. The identification of genomic regions containing loci causally associated with AHR and the demonstration that this trait requires their interaction have important implications for the dissection of the genetic etiology of asthma in humans.
  Physiological Genomics 04/2005; 21(1):105-11. · 2.73 Impact Factor