Comparison of multiple forms of the high mobility group I proteins in rodent and human cells. Identification of the human high mobility group I-C protein

Circular RNA CircSHKBP1 accelerates the proliferation, invasion, angiogenesis, and stem cell-like properties via modulation of microR-766-5p/high mobility group AT-hook 2 axis in laryngeal squamous cell carcinoma

Laryngeal squamous cell carcinoma (LSCC) is a common malignancy in head and neck. Circular SHKBP1 (circSHKBP) exerts momentous functions in the occurrence of many cancers including LSCC. Thus, we investigated the oncogenic capacities of circSHKBP1 in LSCC, and revealed the underlying mechanism as a competing endogenous RNA. The expression levels of circSHKBP1, miR-766-5p, and high mobility group AT-hook 2 (HMGA2) were examined by quantitative real-time PCR and their influences on the overall survival were measured by Kaplan–Meier method. The correlations between circSHKBP1 and miR-766-5p or HMGA2 were detected by Spearman’s rank correlation analysis. In vitro, the influences of circSHKBP1/miR-766-5p/HMGA2 axis on the tumorigenesis of LSCC were examined by CCK-8, transwell, sphere formation, and angiogenesis assays, respectively. circSHKBP1 expression was up-regulated in the LSCC specimens and cell lines. And elevated circSHKBP1 expression was closely linked to poor prognosis. Silencing circSHKBP1 expression restrained cell proliferation, invasion, angiogenesis, stem cell-like properties and tumor growth. We observed that miR-766-5p was down-regulated and negatively correlated to circSHKBP1 in LSCC samples. However, HMGA2 was highly expressed and positively associated with circSHKBP1 in these specimens. Importantly, the levels of circSHKBP1, miR-766-5p, and HMGA2 were closely associated with patients’ clinical parameters including lymph nodes metastasis and TNM stages. Mechanistic analysis clarified that circSHKBP1 sponged miR-766-5p to regulate HMGA2, the target of miR-766-5p. Moreover, miR-766-5p inhibition and overexpression of HMGA2 rescued the tumor-suppressing roles of circSHKBP1 downregulation in LSCC. In conclusion, circSHKBP1 accelerated the tumorigenesis of LSCC via modulating HMGA2 by targeting miR-766-5p.

High mobility group A protein-2 as a tumor cancer diagnostic and prognostic marker: a systematic review and meta-analysis

High mobility group A protein-2 (HMGA2) is an architectural transcription factor that binds to the A/T-rich DNA minor groove and is responsible for regulating transcriptional activity of multiple genes indirectly through chromatin change and assembling enhanceosome. HMGA2 is overexpressed in multiple tumor types, suggesting its involvement in cancer initiation and progression, thus, making it an ideal candidate for cancer diagnostic and prognostic. We performed a systematic review to examine the role of HMGA2 as a universal tumor cancer diagnostic and prognostic marker. We used Reporting Recommendations for Tumor Marker Prognostic Studies to systematically search OvidMedline, PubMed, and the Cochrane Library for English language studies, published between 1995 and June 2019. Meta-analysis provided pooled risk estimates and their 95% confidence intervals (CIs) for an association between overall survival and recurrence of cancers for studies with available estimates. We identified 42 eligible studies with a total of 5123 tumor samples in 15 types of cancer. The pooled percentage of HMGA2 gene expression in tumor samples was 65.14%. Meta-analysis showed that cancer patients with HMGA2 positive have significantly reduced survival, compared to patients without HMGA2 gene [pooled-hazard ratio (HR) = 1.85, 95% CI 1.48-2.22]. There was a positive association between cancer patients with HMGA2 overexpression and cancer recurrence though this association did not reach significance (pooled-HR = 1.44, 95% CI 0.80-2.07). Overexpression of HMGA2 was found in 15 types of cancer. There was an association between HMGA2 overexpression with reduced survival of cancer patients. HMGA2 is thus considered a promising universal tumor marker for prognostics.

The High Mobility Group A1 (HMGA1) Transcriptome in Cancer and Development

BACKGROUND & OBJECTIVES

Chromatin structure is the single most important feature that distinguishes a cancer cell from a normal cell histologically. Chromatin remodeling proteins regulate chromatin structure and high mobility group A (HMGA1) proteins are among the most abundant, nonhistone chromatin remodeling proteins found in cancer cells. These proteins include HMGA1a/HMGA1b isoforms, which result from alternatively spliced mRNA. The HMGA1 gene is overexpressed in cancer and high levels portend a poor prognosis in diverse tumors. HMGA1 is also highly expressed during embryogenesis and postnatally in adult stem cells. Overexpression of HMGA1 drives neoplastic transformation in cultured cells, while inhibiting HMGA1 blocks oncogenic and cancer stem cell properties. Hmga1 transgenic mice succumb to aggressive tumors, demonstrating that dysregulated expression of HMGA1 causes cancer in vivo. HMGA1 is also required for reprogramming somatic cells into induced pluripotent stem cells. HMGA1 proteins function as ancillary transcription factors that bend chromatin and recruit other transcription factors to DNA. They induce oncogenic transformation by activating or repressing specific genes involved in this process and an HMGA1 "transcriptome" is emerging. Although prior studies reveal potent oncogenic properties of HMGA1, we are only beginning to understand the molecular mechanisms through which HMGA1 functions. In this review, we summarize the list of putative downstream transcriptional targets regulated by HMGA1. We also briefly discuss studies linking HMGA1 to Alzheimer's disease and type-2 diabetes.

CONCLUSION

Further elucidation of HMGA1 function should lead to novel therapeutic strategies for cancer and possibly for other diseases associated with aberrant HMGA1 expression.

Value and limitation of immunohistochemical expression of HMGA2 in mesenchymal tumors: about a series of 1052 cases

The high mobility group A (HMGA2) gene encodes a protein that alters chromatin structure and regulates the transcription of many genes; it is implicated in both benign and malignant neoplasias, but its rearrangements are a feature of development of several mesenchymal tumors. Given its implication in these tumors and particularly adipocytic tumors, and the availability of antibodies usable on paraffin-embedded tissues, we evaluated the immunohistochemical expression of this gene in a series of 1052 mesenchymal tumors. The objective was to define the value and limitations of HMGA2 immunohistochemical expression for histotyping, and compare with molecular data reported in the literature. We thus analyzed 880 cases on tissue microarray and 182 cases on whole sections (211 adipocytic tumors, 628 sarcomas, 213 benign mesenchymal tumors, and 10 normal adipose tissues). A nuclear immunostaining was detected in 86% of conventional and intramuscular lipomas, in 86% of well-differentiated liposarcomas and in 67% of dedifferentiated liposarcomas, as opposed to 16% of other benign adipose tumors and to 15% of non-well-differentiated liposarcoma/dedifferentiated liposarcoma sarcomas. Among benign mesenchymal tumors and lesions, it was detected in 90% of nodular fasciitis and in 88% of benign fibrous histiocytomas with respective specificities of 85 and 100%, and in 90% of aggressive angiomyxoma, contrary to other vulvovaginal tumor types, which expressed HMGA2 only rarely. The normal adipose tissue was always negative for HMGA2. Although not specific, immunohistochemical detection of the HMGA2 protein is helpful for the distinction of normal adipose tissue from well-differentiated lesions, particularly on biopsy or on re-excision. It is less sensitive than MDM2/CDK4 for dedifferentiated liposarcomas diagnosis, but it appears more specific to distinguish dedifferentiated liposarcomas from other poorly differentiated sarcomas. Finally, and may be more importantly, HMGA2 is useful for the diagnosis of benign fibrous histiocytoma, nodular fasciitis and vulvovaginal benign mesenchymal tumors.

Gene expressions of HMGI-C and HMGI(Y) are associated with stage and metastasis in colorectal cancer

PURPOSE

The high mobility group proteins (HMGs) include the HMGI family members HMGI-C and HMGI(Y), whose expressions in adult tissues generally correlate with malignant tumor phenotypes. The aim of this study was to assess the relationship of HMGI-C or HMGI(Y) gene expression and prognosis in colorectal cancer patients.

METHODS

The gene expressions of HMGI-C and HMGI(Y) in 31 paired samples of colorectal tumor and corresponding non-tumor were determined by real-time reverse transcription-polymerase chain reaction (RT-PCR).

RESULTS

The expression of HMGI(Y) in a colorectal cancer tumor was associated with Dukes staging (p = 0.044), while, in non-tumor, the expression of this gene was significant with metastasis (p = 0.003). Patients with Dukes stage A and B present high HMGI(Y) expression in non-tumor of colorectal cancer (p = 0.006). However, patients with Dukes stage C and D present high HMGI-C expression in colorectal tumor (p = 0.023). In the non-metastasis group, HMGI(Y) was highly expressed in non-tumor of colorectal cancer. However, in the metastasis group, there was no significant difference between tumor and non-tumor tissues in both HMGI-C and HMGI(Y) gene expressions.

CONCLUSIONS

The HMGI-C and HMGI(Y) quantitations by real-time RT-PCR are associated with Dukes staging and metastasis; hence, the gene expression levels may be useful in clinical practice.

HMGA2 protein expression correlates with lymph node metastasis and increased tumor grade in pancreatic ductal adenocarcinoma

Pancreatic ductal adenocarcinoma is a highly aggressive, lethal human malignancy that continues to elude successful treatment. Although most patients present with metastatic disease, the molecular pathways that underlie tumor progression and metastases are poorly understood. The high mobility group A2 (HMGA2) protein is an architectural transcription factor that has recently been implicated in the development and progression of malignant tumors. Here, we examined HMGA2 gene expression in pancreatic ductal adenocarcinoma to determine if it could be a marker for more advanced disease. By real time quantitative RT-PCR, we showed a marked increase in HMGA2 mRNA in two of three cultured pancreatic ductal adenocarcinoma cell lines compared to normal pancreatic tissue. Using tissue microarrays generated from 124 pancreatic ductal adenocarcinoma cases, we also assessed HMGA2 protein levels by immunohistochemical analysis. We found that HMGA2 nuclear immunoreactivity correlates positively with lymph node metastases and high tumor grade. Our results support a role for HMGA2 in the progression of pancreatic ductal adenocarcinoma and suggest that it could be a useful biomarker and rational therapeutic target in more advanced disease.

HMGA2 participates in transformation in human lung cancer

Although previous studies have established a prominent role for HMGA1 (formerly HMG-I/Y) in aggressive human cancers, the role of HMGA2 (formerly HMGI-C) in malignant transformation has not been clearly defined. The HMGA gene family includes HMGA1, which encodes the HMGA1a and HMGA1b protein isoforms, and HMGA2, which encodes HMGA2. These chromatin-binding proteins function in transcriptional regulation and recent studies also suggest a role in cellular senescence. HMGA1 proteins also appear to participate in cell cycle regulation and malignant transformation, whereas HMGA2 has been implicated primarily in the pathogenesis of benign, mesenchymal tumors. Here, we show that overexpression of HMGA2 leads to a transformed phenotype in cultured lung cells derived from normal tissue. Conversely, inhibiting HMGA2 expression blocks the transformed phenotype in metastatic human non-small cell lung cancer cells. Moreover, we show that HMGA2 mRNA and protein are overexpressed in primary human lung cancers compared with normal tissue or indolent tumors. In addition, there is a statistically significant correlation between HMGA2 protein staining by immunohistochemical analysis and tumor grade (P < 0.001). Our results indicate that HMGA2 is an oncogene important in the pathogenesis of human lung cancer. Although additional studies with animal models are needed, these findings suggest that targeting HMGA2 could be therapeutically beneficial in lung cancer and other cancers characterized by increased HMGA2 expression.

Specific recognition of AT-rich DNA sequences by the mammalian high mobility group protein AT-hook 2: a SELEX study

The mammalian high mobility group protein AT-hook 2 (HMGA2) is a transcriptional factor involved in cell differentiation and transformation. Disruption of its normal expression pattern is directly linked to oncogenesis and obesity. HMGA2 contains three "AT-hook" DNA binding domains, which specifically bind to the minor groove of AT-rich sequences. Using a PCR-based systematic evolution of ligands by exponential enrichment (SELEX) procedure, we have identified two consensus sequences for HMGA2, 5'-ATATTCGCGAWWATT-3' and 5'-ATATTGCGCAWWATT-3', where W represents A or T. These two consensus sequences have a unique and interesting feature: the first five base pairs are AT-rich, the middle four base pairs are GC-rich, and the last six base pairs are AT-rich. Our results showed that all three of these segments are critical for high-affinity binding of HMGA2 to DNA. For example, if one of the AT-rich sequences is mutated to a non-AT-rich sequence, the DNA binding affinity of HMGA2 is reduced at least 100-fold. Intriguingly, if the GC-segment is replaced by an AT-rich segment, the binding affinity of HMGA2 is reduced approximately 5-fold. Identification of the consensus sequences for HMGA2 represents an important step toward finding its binding sites within the genome.

Energetics of binding the mammalian high mobility group protein HMGA2 to poly(dA-dT)2 and poly(dA)-poly(dT)

The mammalian high mobility group protein A2 (HMGA2) is a chromosomal architectural transcription factor involved in oncogenesis and cell transformation. It has three "AT-hook" DNA binding domains, which specifically bind to the minor groove of AT DNAs. The interaction of HMGA2 with poly(dA-dT)2 and poly(dA)poly(dT) has been investigated using the ethidium displacement assay, isothermal titration calorimetry, and UV melting studies. Each AT hook DNA binding domain was found to bind to 5 bp and each HMGA2 molecule binds to 15 bp. Although an individual AT hook DNA binding domain binds to AT DNAs with moderate affinity, HMGA2 binds with very high affinity to both DNAs in solutions containing 20 mM Na+ at 25 degrees C. The K(a) and binding enthalpy for poly(dA-dT)2 were determined to be, respectively, 1.9x10(14)M(-1) and -29.1(+/-0.5)kcal/mol. The binding reaction is enthalpy-driven with a favorable free energy of -19.5 kcal/mol and unfavorable entropy of -32.5 cal/mol K (-TDeltaS= +9. 7kcal/mol) at a 1M reference state. Interestingly, although HMGA2 binds to poly(dA)poly(dT) with a binding constant of 9.6x10(12) M(-1), the binding reaction is entropy-driven with an unfavorable enthalpy of +0.6 kcal/mol, a free energy of -17.7 kcal/mol and an entropy of +61.4 cal/mol K (-TDeltaS=-18.3 kcal/mol) at the 1 M state. The enthalpy-entropy compensation is similar to that of several minor groove-binding drugs such as netropesin, distamycin A and Hoechst33258 and may be a reflection of dehydration difference of different ligand-DNA complexes. The salt-dependence of the binding constant of HMGA2 with both DNAs showed that electrostatic interaction is a dominant force for the binding reactions. The temperature dependence of binding enthalpy for poly(dA-dT)2 indicates a large heat capacity of binding of -705(+/-113) cal/molK, consistent with an important role of solvent displacement in the linked folding/binding processes in this system.

Showing your ID: intrinsic disorder as an ID for recognition, regulation and cell signaling

Regulation, recognition and cell signaling involve the coordinated actions of many players. To achieve this coordination, each participant must have a valid identification (ID) that is easily recognized by the others. For proteins, these IDs are often within intrinsically disordered (also ID) regions. The functions of a set of well-characterized ID regions from a diversity of proteins are presented herein to support this view. These examples include both more recently described signaling proteins, such as p53, alpha-synuclein, HMGA, the Rieske protein, estrogen receptor alpha, chaperones, GCN4, Arf, Hdm2, FlgM, measles virus nucleoprotein, RNase E, glycogen synthase kinase 3beta, p21(Waf1/Cip1/Sdi1), caldesmon, calmodulin, BRCA1 and several other intriguing proteins, as well as historical prototypes for signaling, regulation, control and molecular recognition, such as the lac repressor, the voltage gated potassium channel, RNA polymerase and the S15 peptide associating with the RNA polymerase S-protein. The frequent occurrence and the common use of ID regions in important protein functions raise the possibility that the relationship between amino acid sequence, disordered ensemble and function might be the dominant paradigm for the molecular recognition that serves as the basis for signaling and regulation by protein molecules.

In Vivo Posttranslational Modifications of the High Mobility Group A1a Proteins in Breast Cancer Cells of Differing Metastatic Potential†

The high mobility group (HMG) proteins are important modulators of chromatin structure and gene transcription. Overexpression of HMGA1 proteins in vivo induces neoplastic transformation and promotes a highly metastatic cellular phenotype. This study focuses on characterization of HMGA1a in vivo posttranslational modification (PTM) patterns found in a nonmetastatic and two metastatic lines of MCF-7 human breast cancer cells of differing tumorigenic potential. PTM types and the amino acids on which they occur were identified by matrix-assisted laser desorption ionization time-of-flight (MALDI-TOF) mass spectrometry. Mass analysis was restricted to MALDI peaks having less than +/-150 parts per million (ppm) error, thereby holding our analysis to a more stringent criterion than previously published work with the HMG proteins. Validation of MALDI-TOF MS analysis was accomplished utilizing electrospray ionization tandem mass spectrometry (ESI MS/MS) and manual analysis of ion fragmentation spectra. Patterns and sites of PTMs identified in this study suggest that HMGA1a proteins, like the histones, exhibit a biochemical modification "code" that relates to cellular function. For example, both increased levels of acetylation and a previously unidentified dimethylation of both lysine and arginine residues were found on HMGA1a proteins from metastatic cells compared to proteins found in their nonmetastatic precursors. Additionally, the types of modification present on lysine-45 (e.g., unmodified, acetylation, or dimethylation) varied, depending on the metastatic potential of cells. These findings suggest that examination of the PTM patterns on HMGA1 proteins may provide valuable information concerning the physiological and phenotypic state of mammalian cells.

Nuclear phosphoproteins HMGA and their relationship with chromatin structure and cancer

The structural characteristics of the three nuclear phosphoproteins of the high mobility group A family are outlined and related to their participation in chromatin structure alteration in many biological processes such as gene expression, neoplastic transformation, differentiation, and apoptosis. The elevated expression of these proteins in tumor cells and their post-translational modifications, such as phosphorylation, acetylation and methylation, are discussed and suggested as suitable targets for cancer chemotherapy.

DNA microarray screening of differential gene expression in bone marrow samples from AML, non-AML patients and AML cell lines

This study used cDNA microarray technology to compare gene expression profiles in acute myeloblastic leukaemia (AML) with cDNA dot-blot and real time PCR analysis of cDNA transcripts to confirm array data. Patient AML marrow samples and AML cell lines were compared with normal/non-AML samples. Screening revealed five particular genes to be significantly differentially expressed across the sample groups. The migration-inhibitory factor-related-proteins 8 and 14 (MRP-8 and MRP-14) genes, the products of which inhibit cell migration and differentiation were the most highly expressed in non-malignant cells. The high-mobility-group-protein gene (HMG-1) was up regulated in leukaemic samples and cell lines, which may be associated with aggressive disease. Also upregulated in malignant samples were genes encoding c-myc and glutathione-S-transferase pi (GSTP), the latter implicated in chemotherapy resistance. Faulty expression of such genes may contribute to the pathogenesis of AML and resistance to treatment.

Derepression of HMGA2 gene expression in retinoblastoma is associated with cell proliferation

To assess whether retinoblastoma formation is associated with the expression of high mobility group (HMG) A2 protein, a transcription factor that is highly expressed during embryogenesis and completely repressed in normal adult tissues, we performed Northern and Western blots and RT-PCR analyses, and immunohistochemistry to test for HMGA2 expression. We used established retinoblastoma cell lines in tumors grown in nude mice and clinical retinoblastoma specimens, and contrasted these tumors with normal embryonic and adult retina. Adenoviral-mediated antisense experiments were conducted on the retinoblastoma cell lines to suppress HMGA2 expression and determine if cell proliferation is HMGA2-dependent. We also transfected a retinoblastoma cell line to identify cis-regulatory elements and transcription initiation sites on the HMGA2 gene promoter. HMGA2 gene expression was silenced in terminally differentiated retina of 6-wk-old mice, but it was detected in retina of a 13.5-d postcoitum embryo. Reactivation of HMGA2 gene expression was observed in the retinoblastoma cell lines Y79, WERI-Rb1, and TOTL-1, in tumors derived from some of these cells propagated in nude mice, and in a high frequency of retinoblastomas excised from human patients. This suggests that expression of HMGA2 gene in retinoblastoma cells involves a derepression process. By using an antisense approach to block HMGA2 expression, we observed a decrease in the number of proliferating retinoblastoma cells. As a 1st step toward understanding HMGA2 gene reactivation in retinoblastoma, we mapped the 2 transcription initiation sites and associated positive regulatory elements within the WERI-Rb1 cells. Our discovery of derepression of HMGA2 gene expression in retinoblastoma provides the 1st evidence that this protein might contribute to neoplastic transformation of retina cells.

During apoptosis of tumor cells HMGA1a protein undergoes methylation: identification of the modification site by mass spectrometry

Programmed cell death is characterized by posttranslational modifications of a limited and specific set of nuclear proteins. We demonstrate that during apoptosis of different types of tumor cells there is a monomethylation of the nuclear protein HMGA1a that is associated to its previously described hyperphosphorylation/dephosphorylation process. HMGA1a methylation is strictly related to the execution of programmed cell death and is a massive event that involves large amounts of the protein. In some tumor cells, HMGA1a protein is already methylated to an extent that depends on cell type. The degree of methylation in any case definitely increases during apoptosis. In the studied cell systems (human leukaemia, human prostate tumor, and rat thyroid transformed cells) among the low-molecular-mass HMG proteins, only HMGA1a was found to be methylated. A tryptic digestion map of HPLC-purified HMGA1a protein showed that methylation occurs at arginine 25 in the consensus G(24)R(25)G(26) that belongs to one of the DNA-binding AT-hooks of the protein. An increase of HMGA1a methylation could be related to heterochromatin and chromatin remodeling of apoptotic cells.

HMG-I/Y in human breast cancer cell lines

The HMG-I/Y gene encodes the HMG-I and -Y architectural, chromatin binding proteins originally identified based on their association with chromosomal DNA. HMG-I/Y proteins bind to AT-rich regions in chromosomal DNA and alter gene expression. Increased HMG-I/Y protein expression also correlates with neoplastic transformation. Previous work from our laboratory has shown that HMG-I/Y is a direct c-Myc target gene involved in neoplastic transformation in Burkitt's lymphoma. We also observed that HMG-I/Y proteins have several oncogenic properties. In this report, we show that HMG-I/Y proteins are increased in several human breast cancer cell lines compared to a human breast cell line derived from normal breast cells. Decreasing HMG-I/Y proteins using an antisense ribozyme approach inhibits transformation in human breast cancer cells, suggesting that HMG-I/Y is important for the transformed phenotype observed in these cells. In addition, increased expression of the HMG-I isoform in normal human breast cells leads to transformation. These results suggest that HMG-I/Y is an oncogene important in the pathogenesis of human breast cancer. Although additional studies with animal models are needed, the antisense experiments, which result in blocking transformation suggest that this approach may have therapeutic potential in patients with breast cancer characterized by increased HMG-I/Y expression.

A polypyrimidine/polypurine tract within the Hmga2 minimal promoter: a common feature of many growth-related genes

HMGA2 is an architectural nuclear factor which plays an important role in development and tumorigenesis, but mechanisms regulating its expression are largely unknown. The proximal promoters of the mouse and human genes coding for HMGA2 contain a conserved polypyrimidine/polypurine (ppyr/ppur) element which constitutes a multiple binding site for Sp1 and Sp3 transcription factors. In the present study we report that this region can adopt a single-stranded DNA conformation, as demonstrated in vitro by S1 nuclease sensitivity on supercoiled plasmids, indicative of an intramolecular triple-helical H-DNA structure. Moreover, we find that PTB (polypyrimidine tract binding protein), a member of the hnRNP family, binds the pyrimidine strand of Hmga2 as well as similar ppyr/ppur elements of the c-Ki-ras (R.Y) and c-myc P1 promoters. Transfection experiments indicate that non-B-DNA conformers of the ppyr/ppur tract of the Hmga2 promoter contribute to positive transcriptional activity. We propose a transcriptional mechanism, acting on the Hmga2 non-B-DNA structure and functioning through interconversion between double-stranded and single-stranded DNA, that seems to be adopted by an increasing number of genes, mainly growth-related.

Molecular biology of HMGA proteins: hubs of nuclear function

Members of the HMGA (a.k.a. HMGI/Y) family of 'high mobility group' (HMG) proteins participate in a wide variety of nuclear processes ranging from chromosome and chromatin mechanics to acting as architectural transcription factors that regulate the expression of numerous genes in vivo. As a consequence, they function in the cell as highly connected 'nodes' of protein-DNA and protein-protein interactions that influence a diverse array of normal biological processes including growth, proliferation, differentiation and death. The HMGA proteins, likewise, participate in pathological processes by, for example, acting as regulators of viral gene transcription and by serving as host-supplied proteins that facilitate retroviral integration. HMGA genes are bona fide proto-oncogenes that promote tumor progression and metastasis when overexpressed in cells. High constitutive HMGA protein levels are among the most consistent feature observed in all types of cancers with increasing concentrations being correlated with increasing malignancy. The intrinsic attributes that endow the HMGA proteins with these remarkable abilities are a combination of structural, biochemical and biological characteristics that are unique to these proteins. HMGA proteins have little, if any, secondary structure while free in solution but undergo disordered-to-ordered structural transitions when bound to substrates such as DNA or other proteins. Each protein contains three copies of a conserved DNA-binding peptide motif called the 'AT-hook' that preferentially binds to the minor groove of stretches of AT-rich sequence. In vivo HMGA proteins specifically interact with a large number of other proteins, most of which are transcription factors. They are also subject to many types of in vivo biochemical modifications that markedly influence their ability to interact with DNA substrates, other proteins and chromatin. And, most importantly, both the transcription of HMGA genes and the biochemical modifications of HMGA proteins are direct downstream targets of numerous signal transduction pathways making them exquisitely responsive to various environmental influences. This review covers recent advances that have contributed to our understanding of how this constellation of structural and biological features allows the HMGA proteins to serve as central 'hubs' of nuclear function.

HMGI/Y proteins: flexible regulators of transcription and chromatin structure

The mammalian HMGI/Y (HMGA) non-histone proteins participate in a wide variety of cellular processes including regulation of inducible gene transcription, integration of retroviruses into chromosomes and the induction of neoplastic transformation and promotion of metastatic progression of cancer cells. Recent advances have contributed greatly to our understanding of how the HMGI/Y proteins participate in the molecular mechanisms underlying these biological events. All members of the HMGI/Y family of 'high mobility group' proteins are characterized by the presence of multiple copies of a conserved DNA-binding peptide motif called the 'AT hook' that preferentially binds to the narrow minor groove of stretches of AT-rich sequence. The mammalian HMGI/Y proteins have little, if any, secondary structure in solution but assume distinct conformations when bound to substrates such as DNA or other proteins. Their intrinsic flexibility allows the HMGI/Y proteins to participate in specific protein-DNA and protein-protein interactions that induce both structural changes in chromatin substrates and the formation of stereospecific complexes called 'enhanceosomes' on the promoter/enhancer regions of genes whose transcription they regulate. The formation of such regulatory complexes is characterized by reciprocal inductions of conformational changes in both the HMGI/Y proteins themselves and in their interacting substrates. It may well be that the inherent flexibility of the HMGI/Y proteins, combined with their ability to undergo reversible disordered-to-ordered structural transitions, has been a significant factor in the evolutionary selection of these proteins for their functional role(s) in cells.

A link between apoptosis and degree of phosphorylation of high mobility group A1a protein in leukemic cells

Nuclear phosphoprotein HMGA1a, high mobility group A1a, (previously HMGI) has been investigated during apoptosis. A change in the degree of phosphorylation of HMGA1a has been observed during apoptosis induced in four leukemic cell lines (HL60, K562, NB4, and U937) by drugs (etoposide, camptothecin) or herpes simplex virus type-1. Both hyper-phosphorylation and de-phosphorylation of HMGA1a have been ascertained by liquid chromatography-mass spectrometry. Hyper-phosphorylation (at least five phosphate groups/HMGA1a molecule) occurs at the early apoptotic stages and is probably related to HMGA1a displacement from DNA and chromatin release from the nuclear scaffold. De-phosphorylation (one phosphate or no phosphate groups/HMGA1a molecule) accompanies the later formation of highly condensed chromatin in the apoptotic bodies. We report for the first time a direct link between the degree of phosphorylation of HMGA1a protein and apoptosis according to a process that involves the entire amount of HMGA1a present in the cells and, consequently, whole chromatin. At the same time we report that variously phosphorylated forms of HMGA1a protein are also mono-methylated.

Architectural transcription factor HMGI(Y) promotes tumor progression and mesenchymal transition of human epithelial cells

Numerous studies have demonstrated that overexpression or aberrant expression of the HMGI(Y) family of architectural transcription factors is frequently associated with both neoplastic transformation of cells and metastatic tumor progression. Little is known, however, about the molecular roles played by the HMGI(Y) proteins in these events. Here we report that human breast epithelial cells harboring tetracycline-regulated HMGI(Y) transgenes acquire the ability to form both primary and metastatic tumors in nude mice only when the transgenes are actively expressed. Unexpectedly, the HMG-Y, rather than the HMG-I, isoform of these proteins is the most effective elicitor of both neoplastic transformation and metastatic progression in vivo. Furthermore, expression of either antisense or dominant-negative HMGI(Y) constructs inhibits both the rate of proliferation of tumor cells and their ability to grow anchorage independently in soft agar. Array analysis of transcription profiles demonstrates that the HMG-I and HMG-Y isoform proteins each modulate the expression of distinctive constellations of genes known to be involved in signal transduction, cell proliferation, tumor initiation, invasion, migration, induction of angiogenesis, and colonization. Immunohistochemical analyses of tumors formed in nude mice indicate that many have undergone an epithelial-mesenchymal transition in vivo. Together, these findings demonstrate that overexpression of the HMGI(Y) proteins, more specifically, the HMG-Y isoform protein, is causally associated with both neoplastic transformation and metastatic progression and suggest that induction of integrins and their signaling pathways may play significant molecular roles in these biological events.

HMG-I/Y, a new c-Myc target gene and potential oncogene

The HMG-I/Y gene encodes the HMG-I and HMG-Y proteins, which function as architectural chromatin binding proteins important in the transcriptional regulation of several genes. Although increased expression of the HMG-I/Y proteins is associated with cellular proliferation, neoplastic transformation, and several human cancers, the role of these proteins in the pathogenesis of malignancy remains unclear. To better understand the role of these proteins in cell growth and transformation, we have been studying the regulation and function of HMG-I/Y. The HMG-I/Y promoter was cloned, sequenced, and subjected to mutagenesis analysis. A c-Myc-Max consensus DNA binding site was identified as an element important in the serum stimulation of HMG-I/Y. The oncoprotein c-Myc and its protein partner Max bind to this site in vitro and activate transcription in transfection experiments. HMG-I/Y expression is stimulated by c-Myc in a Myc-estradiol receptor cell line in the presence of the protein synthesis inhibitor cycloheximide, indicating that HMG-I/Y is a direct c-Myc target gene. HMG-I/Y induction is decreased in Myc-deficient fibroblasts. HMG-I/Y protein expression is also increased in Burkitt's lymphoma cell lines, which are known to have increased c-Myc protein. Like Myc, increased expression of HMG-I protein leads to the neoplastic transformation of both Rat 1a fibroblasts and CB33 cells. In addition, Rat 1a cells overexpressing HMG-I protein form tumors in nude mice. Decreasing HMG-I/Y proteins using an antisense construct abrogates transformation in Burkitt's lymphoma cells. These findings indicate that HMG-I/Y is a c-Myc target gene involved in neoplastic transformation and a member of a new class of potential oncogenes.

Binding of HMG-I(Y) imparts architectural specificity to a positioned nucleosome on the promoter of the human interleukin-2 receptor alpha gene

Transcriptional induction of the interleukin-2 receptor alpha-chain (IL-2Ralpha) gene is a key event regulating T-cell-mediated immunity in mammals. In vivo, the T-cell-restricted protein Elf-1 and the general architectural transcription factor HMG-I(Y) cooperate in transcriptional regulation of the human IL-2Ralpha gene by binding to a specific positive regulatory region (PRRII) in its proximal promoter. Employing chromatin reconstitution analyses, we demonstrate that the binding sites for both HMG-I(Y) and Elf-1 in the PRRII element are incorporated into a strongly positioned nucleosome in vitro. A variety of analytical techniques was used to determine that a stable core particle is positioned over most of the PRRII element and that this nucleosome exhibits only a limited amount of lateral translational mobility. Regardless of its translational setting, the in vitro position of the nucleosome is such that DNA recognition sequences for both HMG-I(Y) and Elf-1 are located on the surface of the core particle. Restriction nuclease accessibility analyses indicate that a similarly positioned nucleosome also exists on the PRRII element in unstimulated lymphocytes when the IL-2Ralpha gene is silent and suggest that this core particle is remodeled following transcriptional activation of the gene in vivo. In vitro experiments employing the chemical cleavage reagent 1,10-phenanthroline copper (II) covalently attached to its C-terminal end demonstrate that HMG-I(Y) protein binds to the positioned PRRII nucleosome in a direction-specific manner, thus imparting a distinct architectural configuration to the core particle. Together, these findings suggest a role for the HMG-I(Y) protein in assisting the remodeling of a critically positioned nucleosome on the PRRII promoter element during IL-2Ralpha transcriptional activation in lymphocytes in vivo.

Architecture of high mobility group protein I-C.DNA complex and its perturbation upon phosphorylation by Cdc2 kinase

The high mobility group I-C (HMGI-C) protein is an abundant component of rapidly proliferating undifferentiated cells. High level expression of this protein is characteristic for early embryonic tissue and diverse tumors. HMGI-C can function as an architectural factor enhancing the activity of transcription factor NF-kappaB on the beta-interferon promoter. The protein has three minor groove DNA-binding domains (AT-hooks). Here, we describe the complex of HMGI-C with a fragment of the beta-interferon promoter. We show that the protein binds to NRDI and PRDII elements of the promoter with its first and second AT-hook, respectively. Phosphorylation by Cdc2 kinase leads to a partial derailing of the AT-hooks from the minor groove, affecting mainly the second binding domain. In contrast, binding to long AT stretches of DNA involves contacts with all three AT-hooks and is marginally sensitive to phosphorylation. Our data stress the importance of conformation of the DNA binding site and protein phosphorylation for its function.

A novel downstream positive regulatory element mediating transcription of the human high mobility group (HMG) I-C gene

The high mobility group (HMG) I proteins are small, non-histone chromosomal proteins that promote gene activation during development and within rapidly dividing cells. They do so by facilitating enhanceosome formation on inducible genes, via both protein/DNA and protein/protein interactions. The HMG I-C gene is tightly regulated, normally being expressed exclusively during embryonic development. However, HMG I-C expression is also observed frequently in a number of tumor types, and this expression has been shown to contribute to the malignant transformation process. With the aim of dissecting pathways that lead to aberrant expression of HMG I-C in tumor cells, we have analyzed HMG I-C gene regulation in the human hepatoma cell line PLC/PRF/5. One of the two HMG I-C transcripts detected in this cell line originates from a novel downstream initiation site at nucleotide -161 relative to the first methionine. Transcription from the downstream initiation site is mediated by a PRE located between nt -222 and -217. We show here that the Sp1 and Sp3 transcription factors interact with the PRE and transactivate the HMG I-C promoter in a cooperative fashion. This study provides the first characterization of this downstream HMG I-C promoter.

Expression of the HMGI(Y) gene in human colorectal cancer

Expression of HMGI(Y), a nucleoprotein that binds to A/T rich sequences in the minor groove of the DNA helix, is observable in neoplastically transformed cells but not in normal cells. We have analyzed HMGI(Y) expression in colorectal cancer and evaluated its clinicopathologic significance. HMGI(Y) mRNA was measured by CRT-PCR (competitive reverse transcription-polymerase chain reaction). Immunohistochemical staining for HMGI(Y), p53 and Ki-67 was performed in the same colon cancer tissues, and the results in colorectal tissues were similar to those of RT-PCR. HMGI(Y) expression evidenced by RT-PCR was observed in 63 of 64 (98.4%) colorectal cancer samples, and 2 of 5 (40%) adenomatous polyps, whereas 21 normal colon samples were negative (p<0.001). High HMGI(Y) expression using CRT-PCR was found in colon cancers with a high Ki-67 labeling index (p<0.001). There was no significant correlation between the levels of HMGI(Y) expression and stage, tumor size, lymph node metastasis, histologic grade and immunohistochemical status of p53. Our results indicate that the HMGI(Y) expression may occur at an early stage of carcinogenesis and correlate with cell proliferation. Int. J. Cancer (Pred. Oncol.), 84:376-380, 1999.

Cell cycle regulation and functions of HMG-I(Y)

Members of the HMG-I(Y) family of "high mobility group" (HMG) proteins are distinguished from other nonhistone chromatin proteins by their ability to preferentially recognize the structure of the narrow minor groove of A.T-sequences of B-form DNA. In vivo the HMG-I(Y) proteins are localized in the A.T-rich G/Q bands and in the "scaffold-associated regions" (SARs) of metaphase chromosomes. These proteins also share with some of the other "HMG box" proteins the ability to recognize non-B-form structures, such as cruciforms (four-way junctions), as well as the possessing the capacity to introduce both bends and supercoils in substrate DNAs. These characteristics, along with their ability to specifically interact with a number of known transcription factors, enable the HMG-I(Y) proteins to function in vivo as structural transcription factors for a number mammalian genes. The HMG-I(Y) proteins are also in vivo substrates for the cell cycle regulated Cdc2 kinase which phosphorylates the DNA-binding domain(s) of the protein and, as a result, decreases their substrate binding affinity. This reversible in vivo pattern of Cdc2 kinase phosphorylations during the cell cycle is likely to play a major role in mediating the biological function(s) of the HMG-I(Y) proteins.

NF-kappaB mediated transcriptional activation is enhanced by the architectural factor HMGI-C

High mobility group I proteins (HMGI, HMGY and HMGI-C) are a family of low molecular mass non-histone nuclear proteins which constitute an important component of the active chromatin structure. Two members of this family, HMGI and HMGY, have been demonstrated to contribute to the transcriptional regulation of several promoters by interacting with the DNA and with different transcription factors. On the contrary, very little is known about the third member, HMGI-C, which plays an important role during embryonic growth and in the process of cell transformation, its gene being rearranged in a large number of mesenchimal tumors. In this paper we show for the first time that HMGI-C is also able to function as architectural factor, enhancing the activity of a transcription factor, NF-kappaB, through the PRDII element of the beta-interferon enhancer. Moreover we show that this enhancement is absolutely dependent on the binding of HMGI-C to its target sequence. The demonstration that HMGI-C is able to modulate transcription is thus an important initial step in the identification of genes regulated by this factor.

Effects of epidermal growth factor and estrogen on the regulation of the HMG-I/Y gene in human mammary epithelial cell lines

Members of the HMG-I/Y family of high-mobility-group chromatin proteins have been demonstrated to regulate gene expression in human cells in vivo. They are thought to function as gene regulatory molecules by acting as architectural transcription factors that modulate DNA and/or chromatin structure. Numerous studies have indicated that elevated HMG-I/Y gene expression is directly correlated with more advanced cancers and with increased metastatic potential. The inducible expression of the HMG-I/Y gene was studied in two human mammary epithelial cell lines, MCF7 and Hs578T, in the presence, or absence, of either 17 beta-estradiol or epidermal growth factor (EGF). Northern blot analysis indicated that there was no increase in HMG-I/Y mRNA in the nonmetastatic MCF7 cells when they were treated with either 17 beta-estradiol or EGF. In contrast, in the highly metastatic Hs578T cell line, there is a dramatic induction of HMG-I/Y mRNA expression of up to 23-fold when the cells are treated with EGF. mRNA primer extension analysis indicated that only two (of the possible four different) transcription initiation start sites in the HMG-I/Y gene are induced by EGF treatment of the Hs578T cells. Additional experiments demonstrated that in both epithelial cell types HMG-I/Y mRNAs are very stable (tl/2 of approximately 30 hr) and that in the Hs578T cells treated with EGF the cellular concentrations of the HMG-I/Y proteins increase concurrently with the induced mRNA levels. Given that HMG-I/Y proteins are regulators of gene activity whose elevated in vivo concentrations are known to be correlated with increased metastatic potential, these data demonstrating an EGF-induced over-expression of HMG-I/Y in the highly metastatic Hs578T, but not in the nonmetastatic MCF7cells, may have important implications concerning the cellular mechanisms involved in the progression of mammary epithelial tumors.

HMGI-C, a member of the high mobility group family of proteins, is expressed in hematopoietic stem cells and in leukemic cells

The human HMGI-C gene encoding a member of the high mobility group protein family normally is expressed only during embryonic/fetal development but in none of the adult tissues tested so far. Recently, the HMGI-C gene has attracted a lot of interest since its rearrangements seem to underlie the development of frequent benign mesenchymal tumors. We have therefore checked CD34 positive hematopoietic stem cells and their normal and malignant descendants for HMGI-C expression. CD34 positive stem cells from healthy donors and the leukemia samples tested were positive while all peripheral blood samples from healthy volunteers were negative. We have concluded that the expression of the HMGI-C gene in leukemia seems to be a secondary effect due to abnormal stem cell proliferation and might be a sensitive tumor marker for particular types of leukemia.

HMGIC expressed in a uterine leiomyoma with a deletion of the long arm of chromosome 7 along with a 12q14-15 rearrangement but not in tumors showing del(7) as the sole cytogenetic abnormality

Cytogenetic studies on uterine leiomyomas have shown that more than 60% of these tumors possess a normal karyotype and that 30% have clonal chromosomal aberrations. The most frequent changes are aberrations involving 12q14-15 and show rearrangements of the long arm of chromosome 7. Recently, we were able to demonstrate that in a variety of mesenchymal tumors showing 12q14-15 aberrations the HMGIC gene is rearranged thus playing a role in tumorigenesis. Here we report the results of HMGIC expression studies by RT-PCR of five uterine leiomyomas with different karyotypes. The RT-PCR studies were performed on two primary tumors showing a 12q14-15 aberration, one of which with an additional del(7) and three tumors with del(7) as the sole aberration. The tumor with the 12q14-15 aberration as the sole alteration and the leiomyoma with 12q14-15 rearrangement plus deletion of the long arm of chromosome 7 were shown to express HMGIC. In contrast, in all three tumors with the del(7) as the sole aberration no expression of HMGIC was noted.

Expression of HMGI-C, a member of the high mobility group protein family, in a subset of breast cancers: relationship to histologic grade

The high-mobility-group (HMG) protein gene HMGI-C is apparently involved in the genesis of a variety of benign human solid tumors with rearrangements of chromosomal region 12q14-15 affecting the HMGI-C gene. So far, no expression of HMGI-C has been found in adult tissues, and no data are available on the expression of HMGI-C in primary human malignant tumors of epithelial origin. Therefore, we analysed the HMGI-C expression patterns in 44 breast cancer samples and 13 samples of nonmalignant adjacent tissue by hemi-nested reverse transcriptase-polymerase chain reaction for HMGI-C expression. There was no detectable expression of HMGI-C in any nonmalignant adjacent breast tissues analyzed. In contrast, we found expression in 20 of 44 breast cancer samples investigated. In invasive ductal tumors, expression was noted predominantly in tumors with high histologic grade: 17 of 21 breast cancer samples with histologic grade 3 but only three of 16 samples with histologic grades 1 or 2 showed expression of HMGI-C. In addition, all seven lobular breast cancer samples tested did not express HMGI-C. From these results, we concluded that HMGI-C expression may be of pathogenetic or prognostic importance in breast cancer.

Amplification of a rearranged form of the high-mobility group protein gene HMGIC in OsA-CI osteosarcoma cells

Recently the high-mobility group protein gene HMGIC has been found to be rearranged in a variety of benign mesenchymal tumors with 12q13-q15 aberrations, such as angiomyxoma, fibroadenomas of the breast, lipomas, pleomorphic salivary gland adenomas, polyps of the endometrium, pulmonary chondroid hamartomas, and uterine leiomyomas. Here we report on HMGIC aberrations in the osteosarcoma cell line OsA-CI. In Northern blot studies, aberrant HMGIC transcripts were detected. Analysis of cDNA sequence data obtained after 3' rapid amplification of cDNA ends, indicated these to consist of 5' HMGIC sequences encoding the three DNA binding domains fused to ectopic sequences apparently derived from part of the human lumican (keratan sulphate proteoglycan) gene (LUM), which we mapped by fluorescence in situ hybridization (FISH) to chromosome 12q22-q23. Moreover, Southern blot analysis revealed amplification of this fusion gene but not of the 3'HMGIC sequences. This observation was independently confirmed by FISH analysis using yeast artificial chromosome (YAC) and cosmid clones, which furthermore indicated that the amplified 5'HMGIC sequences were contained within an amplicon of about 200 kb. Our results indicate that aberrations in HMGIC might not be restricted to benign mesenchymal tumors.

An endometrial polyp with a rearrangement of HMGI-C underlying a complex cytogenetic rearrangement involving chromosomes 2 and 12

Cytogenetic studies of an endometrial polyp of an 82-year-old patient revealed a karyotype 46,XX,der(2)inv(2)(p25q21)ins(2;12)(p25;q13q14)t(2;12)(q21; q15),der(12)del(12)(q13q14)del(12)(q15). By fluorescence in situ hybridization (FISH) we found the chromosome 12 translocation breakpoint to be mapping within the third intron of the HMGI-C gene also harboring the breakpoints of translocations involving 12q15 seen in uterine leiomyomas, lipomas, pleomorphic adenomas, and pulmonary chondroid hamartomas.

Calcium-dependent ADP-ribosylation of high-mobility-group I (HMGI) proteins

Micrococcal nuclease digestion of nuclei from mouse Lewis lung carcinoma cells releases a protein mixture into the supernatant that lacks histone H1 and contains a full complement of high-mobility-group I (HMGI) proteins (i.e. I, Y and I-C). This implies that all three HMGI proteins are localized at the nuclease-sensitive regions of active chromatin. It is also shown that if Ca2+ ions are present in the nuclear incubation buffer (with or without exogenous nuclease), all three HMGI proteins become ADP-ribosylated. We propose that this modification of HMGI family proteins is part of the general poly(ADP-ribosyl)ation that accompanies DNA damage in apoptosis and other processes.

Mechanisms of murine RANTES chemokine gene induction by Newcastle disease virus

We have previously defined the lipopolysaccharide (LPS)-responsive element (LRE) in the promoters of murine RANTES (regulated on activation normal T-cell expressed) (MuRantes) and murine IP-10/crg-2, chemokines which have potent chemotactic properties for inflammatory cells including monocytes and T lymphocytes. In the present work, we studied the transcriptional mechanism of MuRantes gene induction by virus and compared it with that of LPS in an effort to understand the host responses to virus and bacterial toxins at the molecular level. MuRantes mRNA expression is induced by Newcastle disease virus (NDV) and LPS in the RAW 264.7 macrophage cell line and peritoneal macrophages of LPS-responsive C3HeB/FeJ mice. In LPS-hyporesponsive C3H/HeJ mice, only NDV induces this chemokine gene, indicating that the pathways of transcriptional activation by NDV and LPS are not identical. Using a transient transfection assay, the minimal virus-responsive element (VRE) was localized between nt -175 and -116. The VRE contains previously defined LRE motif 1 (TCAYRCTT) and motif 3 ((T/A)GRTTTCA(G/C)TTT), which were shown to also be important for initiation of transcription by virus. NDV-stimulated nuclear extracts were tested for trans-activating factors able to bind the VRE. The chromosomal protein HMG-I(C) was shown to bind the 3'-A.T-rich domains of the VRE, and the presence of HMG-I(C) was demonstrated in the VRE-protein complex formed with nuclear extracts from NDV-stimulated, but not unstimulated cells. These findings demonstrate the role of HMG-I(C) in activation of MuRantes promoter by NDV.

Differential regulation of a multipromoter gene. Selective 12-O-tetradecanoylphorbol-13-acetate induction of a single transcription start site in the HMG-I/Y gene

The human HMG-I/Y gene, encoding the non-histone "high mobility group" proteins HMG-I and HMG-Y, is transcriptionally activated in human K562 erythroleukemia cells by treatment with 12-O-tetradecanoylphorbol-13-acetate (TPA). TPA treatment induces differentiation of K562 cells within 2-4 days after treatment. In this report, we show that transcriptional activation of the HMG-I/Y gene is dependent on protein synthesis and is an early event (2 h after induction) in the TPA-mediated differentiation process. Of the four functional transcription start sites present in the gene, only one (start site 2) is preferentially induced upon TPA treatment. This is the first report, to our knowledge, of the preferential utilization of a specific transcription start site in response to a particular stimulus in a gene that contains multiple promoters. This indicates that each start site in the gene has the potential to be independently regulated instead of being coordinately controlled as shown in a number of other genes. In addition, sequences upstream of the inducible start site, which contains a TPA-responsive element, mediates TPA inducibility through AP1 (or an AP1-like) transcription factor. The HMG-I/Y proteins function as key regulators of gene expression and play a significant role in chromatin structural changes as well. The cloning and sequence analyses previously reported indicated the structure of the HMG-I/Y gene to be highly complex and predicted its expression to be tightly regulated. The results presented here confirm and extend these earlier findings.

Inhibition of HMGI-C protein synthesis suppresses retrovirally induced neoplastic transformation of rat thyroid cells

Elevated expression of the three high-mobility group I (HMGI) proteins (HMGI, HMGY, and HMGI-C) has previously been correlated with the presence of a highly malignant phenotype in epithelial and fibroblastic rat thyroid cells and in experimental thyroid, lung, mammary, and skin carcinomas. Northern (RNA) blot and run-on analyses demonstrated that the induction of HMGI genes in transformed thyroid cells occurs at the transcriptional level. An antisense methodology to block HMGI-C protein synthesis was then used to analyze the role of this protein in the process of thyroid cell transformation. Transfection of an antisense construct for the HMGI-C cDNA into normal thyroid cells, followed by infection with transforming myeloproliferative sarcoma virus or Kirsten murine sarcoma virus, generated cell lines that expressed significant levels of the retroviral transforming oncogenes v-mos or v-ras-Ki and removed the dependency on thyroid-stimulating hormones. However, in contrast with untransfected cells or cells transfected with the sense construct, those containing the antisense construct did not demonstrate the appearance of any malignant phenotypic markers (growth in soft agar and tumorigenicity in athymic mice). A great reduction of the HMGI-C protein levels and the absence of the HMGI(Y) proteins was observed in the HMGI-C antisense-transfected, virally infected cells. Therefore, the HMGI-C protein seems to play a key role in the transformation of these thyroid cells.

High-mobility-group (HMG) proteins and histone H1 subtypes expression in normal and tumor tissues of mouse

Exhaustive extraction of mouse tissues with perchloric acid has been used together with reverse-phase HPLC and electrophoresis to quantify the amounts of chromosomal proteins HMG17, HMG14 and HMGI, relative to histone H1. Normal lung and thymus contain approximately 3% HMG17/HMG14 but only approximately 2% HMGI. In tumor tissues (Lewis lung carcinoma and lymphoma NQ35), the amount of HMG17/HMG14 is not greatly altered but HMGI levels rise considerably, reaching 10% in Lewis lung carcinoma. HMGI synthesis does not replace HMG17/HMG14 proteins, suggesting that HMGI proteins contribute to the structure of chromatin regions in a manner distinct from those of HMG17/HMG14. Ion-spray mass spectrometry has been used to determine the molecular masses of H1 subtypes from the same four mouse tissues. In addition to the six known species H1 zero, H1a, H1b, H1c, H1d and H1e, a newly defined subtype of mass 21,756 Da from Lewis lung carcinoma, named H1L was identified. Several phosphorylated H1 subtypes have also been defined by mass spectrometry. The combined use of reverse-phase HPLC and electrophoresis permitted quantification of these seven histone H1 subtypes in the four mouse tissues. Increased phosphorylation of H1 subtypes in tumors parallels the phosphorylation of HMGI proteins which are present in great amounts, showing that both are involved as post-translational-modified forms in the structure of the chromatin of neoplastic systems.

Molluscan sperm proteins: Ensis minor

The three major proteins, EM1, EM5 and EM6, from the mature sperm of the bivalve mollusc Ensis minor have been partially sequenced in order to establish which category they belong to and their potential for phosphorylation. Protein EM1 is protamine-like with about 50% basic amino acids, some of which are included in SK(R) repeats. Three SPXX potential phosphorylation sites were observed in the N-terminal domain. EM1 does not fold (Giancotti et al. (1983) Eur. J. Biochem. 136, 509-516). Protein EM6 (approx. 270 residues) is histone H1-like, having a globular domain homologous to other H1 family proteins. The N-domain of EM6 contains SK(R) repeats like EM1, but there are few, if any, SPXX sites in the chain. Proteins EM1 and EM6 are the two proteins specific for mature sperm. Protein EM5, of about 150 residues and present at lower levels than EM1 and EM6, is also an H1-family molecule. A sequence from its globular domain shows close homology to chicken H5 and to sea urchin somatic H1. Its presence may relate to the existence of a low level of nucleosomal structure.

cDNA cloning of the HMGI-C phosphoprotein, a nuclear protein associated with neoplastic and undifferentiated phenotypes

The HMGI-C protein is a nuclear phosphoprotein expressed at high levels in transformed cells. The cDNA encoding the mouse protein has been isolated and the sequence of the encoded protein shows that it is related to the HMGY and I proteins, proteins which bind in the minor groove of DNA containing stretches of A and T. The HMGI-C protein has three short highly basic domains, an acidic C-terminal domain, and potential CDC2/p34 and casein kinase II phosphorylation sites. Analysis of mRNA levels demonstrate that the HMGI-C gene is not expressed in a variety of mouse tissues but is expressed in Lewis lung carcinoma cells.