Outcomes of patients with multiple myeloma harboring chromosome 1q gain/amplification in the era of modern therapy.

Chromosome 1q gain/amplification (1q +) has been reported to be associated with inferior outcomes in multiple myeloma (MM) patients. Big therapeutic advances have shifted the treatment landscape by introducing monoclonal antibodies. There is a relative lack of data on outcomes in patients harboring this alteration in the era of monoclonal antibodies. Baseline characteristics and therapy-related data from newly diagnosed MM patients harboring 1q + detected by fluorescence in situ hybridization (FISH) were collected in a single institution. Among 34 identified subjects, the presence of elevated LDH was found to be associated with shorter overall survival (OS), and increased bone marrow plasma cell percentage (≥ 60%) was associated with worse progression-free survival (PFS). 1q + copy number more than three was associated with both shorter OS and PFS. Additionally, the administration of lenalidomide was associated with superior OS. The use of autologous stem cell transplantation, bortezomib, or daratumumab, was found to have no prognostic benefits in our sample. Lenalidomide may be an optimal therapeutic choice for this population, and future larger studies are warranted to confirm this benefit and further investigate the role of monoclonal antibodies in this subpopulation.

Delineating cell behavior and metabolism of non-melanoma skin cancer in vitro.

Non-melanoma skin cancers - basal cell carcinoma (BCC) and squamous cell carcinoma (SCC) - are the most frequent forms of malignant neoplasm in humans worldwide. The etiology of these carcinomas is multifactorial. In addition to the harmful effect of UV light, altered cross-talk between neoplastic epithelial cells and the supporting dermal fibroblasts contributes to the regulation of tumor cell behavior, growth and survival. Metabolic cooperation between these cell types allows them to adapt and react to changes in their surrounding microenvironment by modifying their cellular bioenergetics and biosynthesis. We characterized the growth, behavior, and metabolic activity of human BCC cells, E-cadherin-competent SCC cells and E-cadherin-suppressed SCC cells in the presence or absence of dermal fibroblasts. In mono-cultures and co-cultures, BCC and SCC cells demonstrated distinct morphology, growth and organizational patterns. These tumor cells also exhibited unique patterns of consumption and secretion profiles of glucose, lactate, acetate, glutamine, glutamate, and pyruvate. In comparison to mono-cultures, growth of fibroblasts with either BCC cells or SCC cells enriched the cell growth environment, allowed for metabolic cooperation between these two cell types, and resulted in alterations in the metabolic profiles of the co-cultures. These alterations were affected by the cancer cell type, culture confluence and the composition of the growth medium. Characterizing the bioenergetics of BCC and SCC cells in the context of tumor-stromal interactions is not only important for further understanding of tumor pathogenesis, but also can illuminate potential new targets for novel, metabolic-based therapies for non-melanoma skin cancers.

Maternal obesity affects fetal neurodevelopmental and metabolic gene expression: a pilot study.

OBJECTIVE: One in three pregnant women in the United States is obese. Their offspring are at increased risk for neurodevelopmental and metabolic morbidity. Underlying molecular mechanisms are poorly understood. We performed a global gene expression analysis of mid-trimester amniotic fluid cell-free fetal RNA in obese versus lean pregnant women. METHODS: This prospective pilot study included eight obese (BMI≥30) and eight lean (BMI<25) women undergoing clinically indicated mid-trimester genetic amniocentesis. Subjects were matched for gestational age and fetal sex. Fetuses with abnormal karyotype or structural anomalies were excluded. Cell-free fetal RNA was extracted from amniotic fluid and hybridized to whole genome expression arrays. Genes significantly differentially regulated in 8/8 obese-lean pairs were identified using paired t-tests with the Benjamini-Hochberg correction (false discovery rate of <0.05). Biological interpretation was performed with Ingenuity Pathway Analysis and the BioGPS gene expression atlas. RESULTS: In fetuses of obese pregnant women, 205 genes were significantly differentially regulated. Apolipoprotein D, a gene highly expressed in the central nervous system and integral to lipid regulation, was the most up-regulated gene (9-fold). Apoptotic cell death was significantly down-regulated, particularly within nervous system pathways involving the cerebral cortex. Activation of the transcriptional regulators estrogen receptor, FOS, and STAT3 was predicted in fetuses of obese women, suggesting a pro-estrogenic, pro-inflammatory milieu. CONCLUSION: Maternal obesity affects fetal neurodevelopmental and metabolic gene expression as early as the second trimester. These findings may have implications for postnatal neurodevelopmental and metabolic abnormalities described in the offspring of obese women.

Global gene expression analysis of term amniotic fluid cell-free fetal RNA.

OBJECTIVE: To identify the tissue expression patterns and biological pathways enriched in term amniotic fluid cell-free fetal RNA by comparing functional genomic analyses of term and second-trimester amniotic fluid supernatants. METHODS: This was a prospective whole genome microarray study comparing eight amniotic fluid samples collected from women at term who underwent prelabor cesarean delivery and eight second-trimester amniotic fluid samples from routine amniocenteses. A functional annotation tool was used to compare tissue expression patterns in term and second-trimester samples. Pathways analysis software identified physiologic systems, molecular and cellular functions, and upstream regulators that were significantly overrepresented in term amniotic fluid. RESULTS: There were 2,871 significantly differentially regulated genes. In term amniotic fluid, tissue expression analysis showed enrichment of salivary gland, tracheal, and renal transcripts as compared with brain and embryonic neural cells in the second trimester. Functional analysis of genes upregulated at term revealed pathways that were highly specific for postnatal adaptation such as immune function, digestion, respiration, carbohydrate metabolism, and adipogenesis. Inflammation and prostaglandin synthesis, two key processes involved in normal labor, were also activated in term amniotic fluid. CONCLUSIONS: Transcriptomic analysis of amniotic fluid cell-free fetal RNA detects fetal maturation processes activated in term pregnancy. These findings further develop the concept of amniotic fluid supernatant as a real-time gene expression "summary fluid" and support its potential for future studies of fetal development.

Proof of concept study to assess fetal gene expression in amniotic fluid by nanoarray PCR.

Microarray analysis of cell-free RNA in amniotic fluid (AF) supernatant has revealed differential fetal gene expression as a function of gestational age and karyotype. Once informative genes are identified, research moves to a more focused platform such as quantitative reverse transcriptase-PCR. Standardized NanoArray PCR (SNAP) is a recently developed gene profiling technology that enables the measurement of transcripts from samples containing reduced quantities or degraded nucleic acids. We used a previously developed SNAP gene panel as proof of concept to determine whether fetal functional gene expression could be ascertained from AF supernatant. RNA was extracted and converted to cDNA from 19 AF supernatant samples of euploid fetuses between 15 to 20 weeks of gestation, and transcript abundance of 21 genes was measured. Statistically significant differences in expression, as a function of advancing gestational age, were observed for 5 of 21 genes. ANXA5, GUSB, and PPIA showed decreasing gene expression over time, whereas CASC3 and ZNF264 showed increasing gene expression over time. Statistically significantly increased expression of MTOR and STAT2 was seen in female compared with male fetuses. This study demonstrates the feasibility of focused fetal gene expression analysis using SNAP technology. In the future, this technique could be optimized to examine specific genes instrumental in fetal organ system function, which could be a useful addition to prenatal care.

Transcriptomic analysis of cell-free fetal RNA suggests a specific molecular phenotype in trisomy 18.

Trisomy 18 is a common human aneuploidy that is associated with significant perinatal mortality. Unlike the well-characterized "critical region" in trisomy 21 (21q22), there is no corresponding region on chromosome 18 associated with its pathogenesis. The high morbidity and mortality of affected individuals has limited extensive investigations. In order to better understand the molecular mechanisms underlying the congenital anomalies observed in this condition, we investigated the in utero gene expression profile of second trimester fetuses affected with trisomy 18. Total RNA was extracted from cell-free amniotic fluid supernatant from aneuploid fetuses and euploid controls matched for gestational age and hybridized to Affymetrix U133 Plus 2.0 arrays. Individual differentially expressed transcripts were obtained by two-tailed t tests. Over-represented functional pathways among these genes were identified with DAVID and Ingenuity(®) Pathways Analysis. Results show that three hundred and fifty-two probe sets representing 251 annotated genes were statistically significantly differentially expressed between trisomy 18 and controls. Only 7 genes (2.8% of the annotated total) were located on chromosome 18, including ROCK1, an up-regulated gene involved in valvuloseptal and endocardial cushion formation. Pathway analysis indicated disrupted function in ion transport, MHCII/T cell mediated immunity, DNA repair, G-protein mediated signaling, kinases, and glycosylation. Significant down-regulation of genes involved in adrenal development was identified, which may explain both the abnormal maternal serum estriols and the pre and postnatal growth restriction in trisomy 18. Comparison of this gene set to one previously generated for trisomy 21 fetuses revealed only six overlapping differentially regulated genes. This study contributes novel information regarding functional developmental gene expression differences in fetuses with trisomy 18.

Functional genomic analysis of amniotic fluid cell-free mRNA suggests that oxidative stress is significant in Down syndrome fetuses.

To characterize the differences between second trimester Down syndrome (DS) and euploid fetuses, we used Affymetrix microarrays to compare gene expression in uncultured amniotic fluid supernatant samples. Functional pathway analysis highlighted the importance of oxidative stress, ion transport, and G protein signaling in the DS fetuses. Further evidence supporting these results was derived by correlating the observed gene expression patterns to those of small molecule drugs via the Connectivity Map. Our results suggest that there are secondary adverse consequences of DS evident in the second trimester, leading to testable hypotheses about possible antenatal therapy for DS.

Array-CGH analysis of cell-free fetal DNA in 10 mL of amniotic fluid supernatant.

BACKGROUND: Previously, we showed that analysis of amniotic fluid (AF) supernatant cell-free fetal (cff) DNA using DNA microarrays (array-CGH) allows for detection of whole chromosome differences between test and reference DNA. Subsequent technical advances have increased both the yield and quality of extracted cffDNA. Here we determined whether array-CGH using smaller volumes of both fresh and frozen AF cffDNA could identify fetal aneuploidy. METHODS: CffDNA was extracted from 10 mL of residual AF supernatant. The test AF samples (n = 10) included one with a normal karyotype, and nine with the following fetal aneuploidies: trisomies 13 (n = 1), 18 (n = 3), 21 (n = 2), trisomy 9 mosaicism (47,XX,+ 9[18]/46,XX[2]), triploidy (69,XXY) and Turner syndrome (45,X). RESULTS: Array-CGH using AF cffDNA from aneuploid fetuses, compared to euploid reference AF cffDNA, detected whole chromosome aneuploidy in 8 of 9 cases tested, including the case of trisomy 9 mosaicism. The case of triploidy was not detected. CONCLUSIONS: CffDNA extracted from 10 mL AF supernatant can be analyzed using array-CGH to correctly identify human chromosome abnormalities. This technology allows for rapid screening of AF samples for whole chromosomal changes by using routinely discarded supernatant, and may augment standard prenatal karyotyping techniques by providing additional molecular information.

Cell-free fetal DNA in amniotic fluid: unique fragmentation signatures in euploid and aneuploid fetuses.

BACKGROUND: Circulating cell-free fetal deoxyribonucleic acids (cffDNA) are novel biomarkers with many clinical applications. Amniotic fluid (AF) is a rich source of cffDNA. We investigated the biophysical characteristics of cffDNA in AF, hypothesizing that they would differ from cffDNA in maternal plasma. METHODS: We obtained 10 mL of fresh AF supernatant from women carrying euploid fetuses (n = 39) and aneuploid fetuses (n = 4). To test the effects of storage and karyotype, samples from euploid fetuses (n = 19) and aneuploid fetuses with trisomies 21 (n = 16), 18 (n = 9), or 13 (n = 3); triploidy (n = 4); or monosomy X (n = 2) were frozen at -80 degrees C. AF cffDNA was characterized by real-time quantitative PCR amplification of glyceraldehyde-3-phosphate dehydrogenase, gel electrophoresis, and analysis of the DNA fragmentation signature. RESULTS: We observed a significant correlation of concentration with gestational age for fresh AF cffDNA from euploid fetuses (R(2) = 0.77, P <0.0001) but not for frozen cffDNA (P = 0.63). The median amount of cffDNA in frozen euploid samples was significantly lower than in fresh samples (P <0.0001). After adjustment for gestational age, there was a statistically significant decrease in the median amount of cffDNA in frozen aneuploidy samples compared with frozen euploid samples (P = 0.0005). Analysis of the cffDNA size distribution showed different and qualitatively unique patterns for each karyotype. CONCLUSIONS: Gestational age, karyotype, and sample storage time affect concentrations and fragment size of AF cff DNA. These effects may be attributable to fundamental differences in tissue sources, excretion modes, or kinetic pathways. Characteristic signature patterns for each common aneuploidy offer the possibility of using DNA fragmentation analysis as a means of triaging AF samples.

The natural history of trisomy 12p.

Trisomy of the short arm of chromosome 12 is a rare chromosomal anomaly, with an estimated incidence of 1/50,000 births. It may present as a pure trisomy (complete or incomplete), as mosaic trisomy, or with other chromosomal abnormalities. Little is known from prior reports about the natural history and life expectancy of these individuals. In this study we describe the long-term outcome and the differences between patients with mosaic trisomy 12p compared to patients with complete trisomy. We present a series of 16 patients with trisomy 12p; 6 of them are older than 10 years. Most patients were born at term with normal or above normal birth weight. Seven were born with congenital anomalies, but no single anomaly was present in more than one individual. A clear and consistent dysmorphic facial pattern was apparent in all of the subjects. Most patients over 7 years old had a seizure disorder. All individuals exhibited developmental delay with speech affected more severely than motor skills. Six patients were described as "being social." Six had severe behavioral problems, and seven had significant sleep disturbances. Facial features of the three adult patients were different than the younger individuals. We show here that the outcome for patients with mosaic trisomy 12p is better than the outcome in complete trisomy 12p or in trisomy 12p with other chromosomal anomalies. We also provide recommendations for the long-term follow-up of patients with trisomy 12p.

Global gene expression analysis of the living human fetus using cell-free messenger RNA in amniotic fluid.

CONTEXT: No molecular biological tests are available to monitor the ongoing development of human fetuses in vivo. OBJECTIVE: To determine whether cell-free fetal messenger RNA (mRNA) in amniotic fluid can be detected using oligonucleotide microarrays to study large-scale gene expression in living human fetuses, with analysis of sex, gestational age, and fetal pathology as variables. DESIGN, SETTING, AND PATIENTS: Four samples of cell-free amniotic fluid were analyzed from pregnant women between 20 and 32 weeks' gestation and undergoing amnioreduction for polyhydramnios associated with twin-twin transfusion syndrome or hydrops fetalis (cases). The control consisted of 6 pooled amniotic fluid samples from women at 17 weeks' gestation and undergoing genetic amniocentesis. After extraction from the normally discarded fraction of amniotic fluid, RNA was amplified twice, labeled, and analyzed using gene expression microarrays. MAIN OUTCOME MEASURE: Relative mRNA expression in cell-free samples of amniotic fluid from fetuses with polyhydramnios at different gestational ages vs cell-free amniotic fluid from a pooled control. RESULTS: Thirty-six percent of 22,283 probe sets represented on the arrays were present in the cell-free amniotic fluid, and a median of 20% of all probe sets differed between cases and the pooled control. Only male samples expressed 1 Y chromosome transcript. The expression of some developmental transcripts, such as surfactant proteins, mucins, and keratins, changed with gestational age by up to 64-fold. A water transporter gene transcript was increased up to 18-fold in both twin-twin transfusion samples. Placental gene transcripts were not present in any samples. CONCLUSIONS: This pilot study demonstrates that cell-free fetal mRNA can be extracted from amniotic fluid and successfully hybridized to gene expression microarrays. Preliminary analysis suggests that gene expression changes can be detected in fetuses of different sexes, gestational age, and disease status. Cell-free mRNA in amniotic fluid appears to originate from the fetus and not the placenta.

Microarray analysis of cell-free fetal DNA in amniotic fluid: a prenatal molecular karyotype.

Metaphase karyotype analysis of fetal cells obtained by amniocentesis or chorionic villus sampling is the current standard for prenatal cytogenetic diagnosis, particularly for the detection of trisomy 21. We previously demonstrated that large quantities of cell-free fetal DNA (cffDNA) are easily extracted from amniotic fluid (AF). In this study, we explored potential clinical applications of AF cffDNA by testing its ability to hybridize to DNA microarrays for comparative genomic hybridization (CGH) analysis. cffDNA isolated from 11 male fetuses showed significantly increased hybridization signals on SRY and decreased signals on X-chromosome markers, compared with female reference DNA. cffDNA isolated from six female fetuses showed the reverse when compared with male reference DNA. cffDNA from three fetuses with trisomy 21 had increased hybridization signals on the majority of the chromosome 21 markers, and cffDNA from a fetus with monosomy X (Turner syndrome) had decreased hybridization signals on most X-chromosome markers, compared with euploid female reference DNA. These results indicate that cffDNA extracted from AF can be analyzed using CGH microarrays to correctly identify fetal sex and aneuploidy. This technology facilitates rapid screening of samples for whole-chromosome changes and may augment standard karyotyping techniques by providing additional molecular information.