John Groffen

Transforming growth factor‐β3 regulates transdifferentiation of medial edge epithelium during palatal fusion and associated degradation of the basement membrane

Studies on transforming growth factor β3 (TGF‐β3) deficient mice have shown that TGF‐β3 plays a critical role in palatogenesis. These null mutant mice have clefting of the secondary palate, caused by a defect in the process of fusion of the palatal shelves. A critical step in mammalian palatal fusion is removal of the medial edge epithelial cells from the midline seam and formation of continuous mesenchyme. To determine in more detail the role of TGF‐β3 in palatogenesis, we cultured TGF‐β3 null mutant and wild‐type control palatal shelves in an organ culture system. The fate of the medial edge epithelial cells was studied in vitro using vital cell labeling and immunohistochemical techniques. Despite clear adherence, the null mutant palatal shelves did not fuse in vitro, but instead the medial edge epithelial cells survived at the midline position, and the basement membrane was resistant towards degradation. Supplementation of the culture medium with the mature form of TGF‐β3 was able to fully correct the defective fusion in the null mutant specimens. Our results demonstrate that the reason for the defective palatal fusion in TGF‐β3 (−/−) samples is not impaired adhesion. Our data define a specific role for TGF‐β3 in the events that control transdifferentiation of the medial edge epithelial cells including degradation of the underlying basement membrane. Dev. Dyn. 209:255–260, 1997.

The chronic myelocytic cell line K562 contains a breakpoint in bcr and produces a chimeric bcr/c-abl transcript.

In the DNAs of all Ph1-positive chronic myelocytic leukemia patients studied to date, a breakpoint on chromosome 22 (the Ph1 chromosome) can be demonstrated with a probe from the bcr (breakpoint cluster region). Although the K562 cell line was established from cells of a chronic myelocytic leukemia patient, we have been unable to detect the Ph1 chromosome by cytogenetic means. Employing a probe from the 5 region of bcr, we have cloned an amplified Ph1 breakpoint fragment from K562. This demonstrates that K562 contains multiple remnants of a Ph1 chromosome with a breakpoint within bcr and thus may serve as a model system for the study of Ph1-positive chronic myelocytic leukemia at a molecular level. The isolation of bcr cDNA sequences shows that parts of bcr encode a protein. Employing K562, we demonstrate the presence of an abnormally sized mRNA species hybridizing to c-abl and to a bcr cDNA probe, indicating the possible consequence of the Ph1 translocation on a transcriptional level in chronic myelocytic leukemia. The isolation and sequencing of a cDNA containing the breakpoint area of this mRNA provide further evidence for its chimeric structure. Cloning of large stretches of chromosomal DNA flanking bcr and c-abl sequences in K562 and identification of the exons participating in the formation of the chimeric mRNA shows that a splice of at least 99 kilobases is made to fuse the 3 bcr exon to the 5 c-abl exon. Furthermore two chimeric cDNAs were isolated containing chromosome 9 sequences that map 43.5 kilobases downstream from the K562 breakpoint. These chromosome 9 sequences neither hybridize to the 8.5-kilobase chimeric c-abl mRNA nor to normal c-abl mRNAs in Hela cells and probably represent incorrect splicing products present in the K562 cell line.

TGFβ signaling plays a critical role in promoting alternative macrophage activation

BackgroundUpon stimulation with different cytokines, macrophages can undergo classical or alternative activation to become M1 or M2 macrophages. Alternatively activated (or M2) macrophages are defined by their expression of specific gene products and play an important role in containing inflammation, removing apoptotic cells and repairing tissue damage. Whereas it is well-established that IL-4 can drive alternative activation, if lack of TGFβ signaling at physiological levels affects M2 polarization has not been addressed.ResultsVav1-Cre x TβRIIfx/fx mice, lacking TβRII function in hematopoietic cells, exhibited uncontrolled pulmonary inflammation and developed a lethal autoimmune syndrome at young age. This was accompanied by significantly increased numbers of splenic neutrophils and T cells as well as elevated hepatic macrophage infiltration and bone marrow monocyte counts. TβRII-/- CD4+ and CD8+ T-cells in the lymph nodes and spleen expressed increased cell surface CD44, and CD69 was also higher on CD4+ lymph node T-cells. Loss of TβRII in bone marrow-derived macrophages (BMDMs) did not affect the ability of these cells to perform efferocytosis. However, these cells were defective in basal and IL-4-induced arg1 mRNA and Arginase-1 protein production. Moreover, the transcription of genes that are typically upregulated in M2-polarized macrophages, such as ym1, mcr2 and mgl2, was also decreased in peritoneal macrophages and IL-4-stimulated TβRII-/- BMDMs. We found that cell surface and mRNA expression of Galectin-3, which also regulates M2 macrophage polarization, was lower in TβRII-/- BMDMs. Very interestingly, the impaired ability of these null mutant BMDMs to differentiate into IL-4 polarized macrophages was Stat6- and Smad3-independent, but correlated with reduced levels of phospho-Akt and β-catenin.ConclusionsOur results establish a novel biological role for TGFβ signaling in controlling expression of genes characteristic for alternatively activated macrophages. We speculate that lack of TβRII signaling reduces the anti-inflammatory M2 phenotype of macrophages because of reduced expression of these products. This would cause defects in the ability of the M2 macrophages to negatively regulate other immune cells such as T-cells in the lung, possibly explaining the systemic inflammation observed in Vav1-Cre x TβRIIfx/fx mice.

C-abl and bcr are rearranged in a Ph1-negative CML patient.

Chromosomal analysis of a patient with chronic myelocytic leukemia (CML) revealed a translocation (9;12) (q34;q21) without a detectable Philadelphia chromosome (Ph1). Using molecular approaches we demonstrate (i) a rearrangement within the CML breakpoint cluster region (bcr) on chromosome 22, and (ii) a joint translocation of bcr and c‐abl oncogene sequences to the derivative chromosome 12. These observations support the view that sequences residing on both chromosome 9 (c‐abl) and 22 (bcr) are involved in the generation of CML and suggest that a subset of Ph1‐negative patients may in fact belong to the clinical entity of Ph1‐positive CML.

Evidence that the phl gene encodes a 160,000-dalton phosphoprotein with associated kinase activity.

In chronic myelocytic leukemia, the human c-abl oncogene is translocated from chromosome 9 to a region on chromosome 22 designated as the breakpoint cluster region (bcr) (A. de Klein, A. Guerts van Kessel, G. Grosveld, C. R. Bartram, A. Hagemeyer, D. Bootsma, N. K. Spurr, N. Heisterkamp, J. Groffen, and J. R. Stephenson, Nature (London) 300:765-767, 1982; J. Groffen, J. R. Stephenson, N. Heisterkamp, A. de Klein, C. R. Bartram, and G. Grosveld, Cell 36:93-99.) Abnormal c-abl homologous mRNA and protein have been detected in the leukemic cells of patients with chronic myelocytic leukemia (E. Canaani, D. Stein-Saltz, E. Aghai, R. P. Gale, A. Berrebi, and E. Januszewicz, Lancet 1:593-595, 1984; S. J. Collins and M. T. Groudine, Proc. Natl. Acad. Sci. USA 80:4813-4817, 1983; R. P. Gale and E. Canaani, Proc. Natl. Acad. Sci. USA 81:5648-5652, 1984; J. B. Konopka, S. M. Watanabe, J. W. Singer, S. J. Collins, and O. N. Witte, Proc. Natl. Acad. Sci. USA 82:1810-1814, 1985). The abnormal mRNA represents a chimeric transcript consisting of 5 bcr and 3 c-abl sequences (G. Grosveld, J. Verwoerd, T. van Agthoven, A. de Klein, K. L. Ramachandran, N. Heisterkamp, K. Stam, and J. Groffen, Mol. Cell. Biol. 6:607-616, 1986; E. Shtivelman, B. Lifshitz, R. B. Gale, and E. Canaani, Nature (London) 315:550-554, 1985; K. Stam, N. Heisterkamp, G. Grosveld, A. de Klein, R. S. Verma, M. Coleman, H. Dosik, and J. Groffen, N. Engl. J. Med. 313:1429-1433, 1985). In the present study, we demonstrated that the abnormal c-abl protein is a fusion protein. In addition, the normal gene encompassing bcr sequences was shown to encode a 160,000-dalton phosphoprotein with an associated serine or threonine kinase activity. We propose that this gene be designated phl, reserving the term bcr for the region within the phl gene encompassing the Ph translocation breakpoints.

Enzyme replacement therapy in a mouse model of aspartylglycosaminuria

Aspartylglycosaminuria (AGU), the most common lysosomal disorder of glycoprotein degradation, is caused by deficient activity of glycosylasparaginase (AGA). AGA‐deficient mice share most of the clinical, biochemical and histopathologic characteristics of human AGU disease. In the current study, recombinant human AGA administered i.v. to adult AGU mice disappeared from the systemic circulation of the animals in two phases predominantly into non‐neuronal tissues, which were rapidly cleared from storage compound aspartylglucosamine. Even a single AGA injection reduced the amount of aspartylglucosamine in the liver and spleen of AGU mice by 90% and 80%, respectively. Quantitative biochemical analyses along with histological and immunohistochemical studies demonstrated that the pathophysiologic characteristics of AGU were effectively corrected in non‐neuronal tissues of AGU mice during 2 wk of AGA therapy. At the same time, AGA activity increased to 10% of that in normal brain tissue and the accumulation of aspartylglucosamine was reduced by 20% in total brain of the treated animals. Immunohistochemical studies suggested that the corrective enzyme was widely distributed within the brain tissue. These findings suggest that AGU may be correctable by enzyme therapy.—Dunder, U., Kaartinen, V., Valtonen, P., Väänänen, E., Kosma, V.‐M., Heisterkamp, N., Groffen, J., Mononen, I. Enzyme replacement therapy in a mouse model of aspartylglycosaminuria. FASEB J. 14, 361–367 (2000)

Nuclear and cytoplasmic location of the FER tyrosine kinase.

The location of the FER protein within the cell was investigated by using subcellular fractionation and immunofluorescence. FER was found in the cytoplasm and in the nucleus, where it was associated with the chromatin fraction. Its ubiquitous expression and its subcellular location indicate that it may be involved in key regulatory processes.

Localization of a gamma-glutamyl-transferase-related gene family on chromosome 22

A gene family encompassing a minimum of four genes or pseudogenes for gamma-glutamyl transferase (GGT; EC 2.3.2.2) is present on chromosome 22q11. We have previously isolated a cDNA related to GGT but clearly not belonging to its gene family. The chromosomal location of this related gene, GGTLA1, has been determined by both isotopic and fluorescence in situ hybridization to metaphase cells and by Southern blot analysis of somatic cell hybrid DNAs. We show that GGTLA1 is part of a distinct gene family, which has at least four members (GGTLA1, GGTLA2, GGTLA3, GGTLA4). At least two loci are located on chromosome 22 within band q11 and proximal to the chronic myelogenous leukemia (CML) breakpoint in BCR (breakpoint cluster region gene). At least one other member is located more distally between the breakpoints found in Ewings sarcoma and CML. Some of the GGT and GGTLA family members are located on NotI restriction enzyme fragments of a similar size. Combined results indicate that a segment of human chromosome 22q11 has undergone largescale amplification events relatively recently in evolution.

Evidence for the pro-oxidant effect of γ-glutamyltranspeptidase–related enzyme

It has been previously reported that the metabolism of reduced glutathione (GSH) by γ-glutamyltranspeptidase (GGT) in the presence of chelated metals leads to free radical generation and lipid peroxidation (LPO). The present study demonstrates for the first time that an established cell line expressing GGT-rel, a human GGT-related enzyme, metabolizes extracellular GSH to cysteinylglycine (CysGly) in a time-dependent manner when cells were incubated in a medium containing 2.5 mM GSH and 25 mM glycylglycine. Supplementation with 150–165 μM Fe3+-EDTA resulted in a reactive oxygen species (ROS) generation process. The resulting data showed a significantly higher level (7.6-fold) of ROS production in the GGT-rel positive cells in comparison with the GGT-rel negative control cells. CysGly and Cys, but not GSH, were responsible for the observed ROS production, as we confirmed by measuring the same process in the presence of Fe3+-EDTA and different thiols. A higher iron reduction and an increased LPO level determined by malondialdehyde HPLC measurement were also found in GGT-rel–overexpressing cells compared to GGT-rel negative cells. Our data clearly indicate that in the presence of iron, not only GGT, but also GGT-rel has a pro-oxidant function by generation of a reactive metabolite (CysGly) and must be taken into account as a potential physiopathological oxidation system.Abstract It has been previously reported that the metabolism of reduced glutathione (GSH) by γ-glutamyltranspeptidase (GGT) in the presence of chelated metals leads to free radical generation and lipid peroxidation (LPO). The present study demonstrates for the first time that an established cell line expressing GGT-rel, a human GGT-related enzyme, metabolizes extracellular GSH to cysteinylglycine (CysGly) in a time-dependent manner when cells were incubated in a medium containing 2.5 mM GSH and 25 mM glycylglycine. Supplementation with 150–165 μM Fe 3+ -EDTA resulted in a reactive oxygen species (ROS) generation process. The resulting data showed a significantly higher level (7.6-fold) of ROS production in the GGT-rel positive cells in comparison with the GGT-rel negative control cells. CysGly and Cys, but not GSH, were responsible for the observed ROS production, as we confirmed by measuring the same process in the presence of Fe 3+ -EDTA and different thiols. A higher iron reduction and an increased LPO level determined by malondialdehyde HPLC measurement were also found in GGT-rel–overexpressing cells compared to GGT-rel negative cells. Our data clearly indicate that in the presence of iron, not only GGT, but also GGT-rel has a pro-oxidant function by generation of a reactive metabolite (CysGly) and must be taken into account as a potential physiopathological oxidation system.

In Vivo Regulation of CrkII and CrkL Proto-oncogenes in the Uterus by Insulin-like Growth Factor-I DIFFERENTIAL EFFECTS ON TYROSINE PHOSPHORYLATION AND ASSOCIATION WITH PAXILLIN

Changes in CrkII and CrkL phosphorylation are associated with insulin-like growth factor receptor activation in cultured cells. We examined whether similar changes also occur following administration of recombinant human insulin-like growth factor-I to the intact animal. In female rats starved overnight, CrkL phosphorylation was significantly increased 12 min after insulin-like growth factor-I administration. Tyrosine phosphorylation of CrkII was not detectable in either control or treated animals. Paxillin, a 65–70-kDa phosphoprotein containing high affinity binding sites common for the Src homology 2 (SH2) domains of CrkII and CrkL, was observed in both CrkII and CrkL immunoprecipitates. Insulin-like growth factor-I treatment stimulated the association of CrkII with paxillin. In contrast, the same treatment resulted in the dissociation of the CrkL-paxillin complex. Similar effects of insulin-like growth factor-I treatment on the association of CrkL with tyrosine phosphorylated paxillin were observed in fibroblasts overexpressing CrkL. This study demonstrates that the activation of the insulin-like growth factor-I receptor induces changes in the tyrosine phosphorylation and protein-protein interactions of the Crk proteins in vivo. The different responses of CrkL and CrkII to insulin-like growth factor-I receptor activation suggest distinct roles for these two adapter proteins in signal transduction.