Richard S. Lemons

RETINOID THERAPY OF CHILDHOOD CANCER

In vitro studies that showed RA could cause growth arrest and differentiation of myelogenous leukemia and neuroblastoma led to clinical trials of retinoids in APL and neuroblastoma that increased survival for both of those diseases. In the case of APL, ATRA has been the drug of choice, and preclinical and clinical data support direct combinations of ATRA with cytotoxic chemotherapy. For neuroblastoma, a phase I study defined a dose of 13-cis-RA, which was tolerable in patients after myeloablative therapy, and a phase III trial that showed postconsolidation therapy with 13-cis-RA improved EFS for patients with high-risk neuroblastoma. Preclinical studies in neuroblastoma indicate that ATRA or 13-cis-RA can antagonize cytotoxic chemotherapy and radiation, so use of 13-cis-RA in neuroblastoma is limited to maintenance after completion of cytotoxic chemotherapy and radiation. A limitation on the antitumor benefit of ATRA in APL is the marked decrease in drug levels that occurs during therapy as a result of induction of drug metabolism, resulting in a shorter drug half-life and decreased plasma levels. Although early studies sought to overcome the pharmacologic limitations of ATRA therapy in APL, the demonstration that ATO is active against APL in RA-refractory patients has led to a focus on studies employing ATO. Use of 13-cis-RA in neuroblastoma has avoided the decreased plasma levels seen with ATRA. It is likely that recurrent disease seen during or after 13-cis-RA therapy in neuroblastoma is due to tumor cell resistance to retinoid-mediated differentiation induction. Studies in neuroblastoma cell lines resistant to 13-cis-RA and ATRA have shown that they can be sensitive, and in some cases collaterally hypersensitive, to the cytotoxic retinoid fenretinide. Fenretinide induces tumor cell cytotoxicity rather than differentiation, acts independently from RA receptors, and in initial phase I trials has been well tolerated. Clinical trials of fenretinide, alone and in combination with ceramide modulators, are in development.

Chromosomal localization of the human hexabrachion (tenascin) gene and evidence for recent reduplication within the gene

Using analysis of rodent-human somatic cell hybrids as well as in situ hybridization of hexabrachion cDNA probes to normal human metaphase chromosomes, we have localized the human hexabrachion gene to chromosome 9, bands q32-q34. We also put forward the hypothesis that there has been a recent reduplication of a small segment of the human hexabrachion gene. We support this hypothesis by comparison of codon usage in this segment of the gene to codon usage in the remainder of the gene. This hypothesis is also supported by comparison of the sequence of human hexabrachion to that of the chicken hexabrachion. In addition, the latter comparison shows that the reduplication most likely occurred after the divergence of mammalian and avian species.

Therapy associated changes in childhood tumors.

Summary: Contemporary treatment regimens for the common solid tumors of childhood have led to increased numbers of post‐treatment pathologic specimens from survivors. Current therapeutic strategies for childhood cancers in North America require an accurate pathologic diagnosis and stratify patients based on combinations of clinical, biological, and pathologic features. In several tumor systems, the pathologic response to therapy also modifies the treatment regimen. Accurate pathologic interpretation of such specimens is critical in providing useful prognostic information for therapeutic decisions. Standardized handling of post‐therapy pathologic specimens, appropriate use of molecular and genetic studies, consideration of the differential diagnoses, and assessment of the potential biologic significance of therapy‐induced pathologic changes are, therefore, critical for patient management and determination of treatment protocols.

Molecular cloning, expression, and chromosomal localization of the gene encoding a human myeloid membrane antigen (gp150).

DNA from a tertiary mouse cell transformant containing amplified human sequences encoding a human myeloid membrane glycoprotein, gp150, was used to construct a bacteriophage lambda library. A single recombinant phage containing 12 kilobases (kb) of human DNA was isolated, and molecular subclones were then used to isolate the complete gp150 gene from a human placental genomic DNA library. The intact gp150 gene, assembled from three recombinant phages, proved to be biologically active when transfected into NIH 3T3 cells. Molecular probes from the gp150 locus annealed with a 4.0-kb polyadenylated RNA transcript derived from human myeloid cell lines and from tertiary mouse cell transformants. The gp150 gene was assigned to human chromosome 15, and was subchromosomally localized to bands q25-26 by in situ hybridization. The chromosomal location of the gp150 gene coincides cytogenetically with the region assigned to the c-fes proto-oncogene, another human gene specifically expressed by myeloid cells.

Acute promyelocytic leukemia

Significant advances have occurred in the diagnosis, treatment, and long-term outcome of patients with acute promyelocytic leukemia (APL). The purpose of this review is to describe the molecular genetics of this disease, the use of all-trans retinoic acid (ATRA) in clinical trials of APL, and the clinical and basic research questions for future investigation. Findings of clinical studies in mainland China using ATRA as induction therapy for patients with APL concurrent with laboratory characterization of the molecular changes in APL have led to worldwide clinical trials of ATRA in the treatment of patients with APL. Major advances in understanding the molecular biology and genetics of APL have occurred over the past 5 years. These findings have been translated into novel treatment strategies using all-trans retinoic acid as a differentiation agent in the induction phase of therapy resulting in improved long-term outcome, reduced morbidity, and lower costs for patients with APL. Advanced molecular techniques are being employed for diagnosis and for monitoring of patient response to treatment.

Localization of the gene encoding insulin-degrading enzyme to human chromosome 10, bands q23→q25

Insulin-degrading enzyme (IDE) is a cytosolic proteinase involved in the cellular processing of insulin. Using somatic cell hybrid analysis and in situ chromosomal hybridization, we have localized the gene encoding IDE to human chromosome 10, bands q23----q25. The murine Ide gene was previously mapped to Chromosome 19; together, these results suggest that the IDE gene is a member of a conserved syntenic group on human chromosome 10, bands q23----q25 and mouse Chromosome 19.

Molecular cytogenetic analysis of a pleuropulmonary blastoma

We report a case of pleuropulmonary blastoma with complex cytogenetic abnormalities, including trisomy 2, trisomy 8, dup(7), der(10) t(8; 10)(q13; q22), add(17), and double minutes (dmin). Fluorescence in situ hybridization FISH analysis demonstrated TP53 deletion and amplification of MYCN; the latter has not been reported in PPB.

A retrospective analysis of treatment‐related hospitalization costs of pediatric, adolescent, and young adult acute lymphoblastic leukemia

This retrospective study examined the longitudinal hospital outcomes (costs adjusted for inflation, hospital days, and admissions) associated with the treatment of pediatric, adolescent, and young adult acute lymphoblastic leukemia (ALL). Patients between one and 26 years of age with newly diagnosed ALL, who were treated at Primary Childrens Hospital (PCH) in Salt Lake City, Utah were included. Treatment and hospitalization data were retrieved from system‐wide cancer registry and enterprise data warehouse. PCH is a member of the Childrens Oncology Group (COG) and patients were treated on, or according to, active COG protocols. Treatment‐related hospital costs of ALL were examined by computing the average annual growth rates (AAGR). Longitudinal regressions identified patient characteristics associated with costs. A total of 505 patients (46.9% female) were included. The majority of patients had B‐cell lineage ALL, 6.7% had T‐ALL, and the median age at diagnosis was 4 years. Per‐patient, first‐year ALL hospitalization costs at PCH rose from

Likelihood of bone recurrence in prior sites of metastasis in patients with high-risk neuroblastoma.

24,197 in 1998 to

Neonatal nonimmune hemolytic anemia.

37,924 in 2012. The AAGRs were 6.1, 13.0, and 7.6% for total, pharmacy, and room and care costs, respectively. Average days (AAGR = 5.2%) and admissions (AAGR = 3.8%) also demonstrated an increasing trend. High‐risk patients had 47% higher costs per 6‐month period in the first 5 years from diagnosis than standard‐risk patients (P < 0.001). Similarly, relapsed ALL and stem cell transplantations were associated with significantly higher costs than nonrelapsed and no transplantations, respectively (P < 0.001). Increasing treatment‐related costs of ALL demonstrate an area for further investigation. Value‐based interventions such as identifying low‐risk fever and neutropenia patients and managing them in outpatient settings should be evaluated for reducing the hospital burden of ALL.