Humans ; Liver Neoplasms ; metabolism ; pathology

Iron metabolism is the process of absorption, transport, storage and conversion and excretion of the essential trace element iron in living organisms. Normal iron metabolism tightly regulates iron content at the systemic and cellular levels through a variety of related proteins to prevent excessive free radicals from being generated during the iron cycle that can damage the body. Various abnormalities in iron metabolism are found in a variety of lymphohaematopoietic tumours and an insidious link between iron metabolism and tumour development has been revealed. Serum ferritin levels and abnormalities of iron transport proteins, transferrin and their receptors can be used as prognostic indicators for lymphohematopoietic tumours and have opened up new directions of diagnosis and treatment, with a large number of novel drugs targeting tumours emerging to date. This article briefly describes the normal iron metabolism process and highlights the progress of research on abnormal iron metabolism in lymphohematopoietic tumors at the systemic and cellular levels.
Hematopoiesis ; Humans ; Iron/metabolism* ; Neoplasms ; Receptors, Transferrin/metabolism* ; Transferrin/metabolism*

Animals ; Colonic Neoplasms ; metabolism ; pathology ; Female ; Humans ; Liver Neoplasms ; metabolism ; secondary ; Lymphatic Metastasis ; Neoplasm Proteins ; metabolism ; Ovarian Neoplasms ; metabolism ; pathology ; Protein Tyrosine Phosphatases ; metabolism ; Stomach Neoplasms ; metabolism ; pathology

Animals ; Antigens, Neoplasm ; genetics ; metabolism ; Biomarkers, Tumor ; genetics ; metabolism ; Brain Neoplasms ; metabolism ; Cell Adhesion Molecules ; genetics ; metabolism ; Digestive System Neoplasms ; metabolism ; Female ; Genital Neoplasms, Female ; metabolism ; Glioma ; metabolism ; Head and Neck Neoplasms ; metabolism ; Humans ; Immunotherapy ; Male ; Prostatic Neoplasms ; metabolism ; Signal Transduction

Tumor cells have unique energy metabolism phenomena, namely high glucose absorption, aerobic glycolysis and high lactic acid production, which are characterized by down-regulation of related proteins involved in oxidative metabolism in tumor cells, and up-regulation of glucose transporters and monocarboxylate transporters. Studies have shown that drugs that target tumor cell glucose metabolism have the ability to selectively kill tumor cells, bringing new hope for tumor treatment. Tumor stem cells are considered to be the root cause of tumor recurrence, metastasis and poor prognosis, and their energy metabolism characteristics have not yet been agreed. Studies have shown that reversing the energy metabolism of tumor stem cells can increase their chemosensitivity. This article reviews recent studies on tumor and tumor stem cell glucose metabolism and the opportunities and challenges of tumor treatment through targeting glucose metabolism, which might provide new ideas and opportunities for clinical tumor therapy.
Energy Metabolism ; Glucose ; metabolism ; Glycolysis ; Humans ; Lactic Acid ; metabolism ; Neoplasms ; metabolism ; Neoplastic Stem Cells ; metabolism

OBJECTIVETo investigate the expression of annexin I in esophageal squamous cell carcinoma (SCC) and carcinomas of other histological types in order to analyze the correlation between the expression of annexin I and carcinogenesis.

METHODSFirst, a set of tissue microarray was established, which consisted of SCC from the esophagus (208 cases), lung, larynx, cervix, and external genital organs; adenocarcinomas from the lung, stomach, colon and rectum, liver, pancreas, breast, thyroid and kidney with 30 cases in each group, meanwhile, the corresponding normal tissue was also obtained for control. Immunohistochemistry was used to detect the expression of annexin I in different types of carcinomas and the corresponding normal controls from different organs. The correlation between the expression of annexin I and the clinicopathological feature was analyzed and compared, which included age, gender, differentiation grade and lymph node metastasis.

RESULTSIt was found that the expression of annexin I was decreased in esophageal SCC, when compared with normal esophageal squamous epithelia (P < 0.001), the similarity was also found in SCC of the lung, larynx and cervix. However, though negative in normal epidermis, annexin I expression was detected in some cases with SCC from external genital organs. Annexin I was found to be overexpressed in adenocarcinomas of the lung, stomach, colon and rectum, liver, pancreas, breast, thyroid and kidney, particularly very strong expression of annexin I was seen in lung adenocarcinoma, uterine endometrioid adenocarcinoma and ovarian serous adenocarcinoma. Interestingly, it was found to be positive in all thyroid papillary carcinomas, but negative in all normal thyroid glands. However, annexin I expression was found to be negative in all hepatocellular carcinoma and normal hepatocytes; and it was only detected in myoepithelium of normal breast tissue, but not in ductal luminal cells, and rarely in infiltrating ductal adenocarcinoma. In SCC, annexin I expression was stronger in well differentiated ones than that in the poorly differentiated ones. However, contrasting with SCC, in the adenocarcinomas from different organs, annexin I expression was much stronger in poorly differentiated ones than that in the well differentiate ones, especially in the adenocarcinomas from stomach, colon and rectum, pancreas, ovarian and kidney.

CONCLUSIONAnnexin I expression is quite different among different types of carcinomas, and is correlated with histopathological type and differentiation grade. Further study is needed to investigate its role in the carcinogenesis.

Adenocarcinoma ; metabolism ; pathology ; Annexin A1 ; metabolism ; Carcinoma, Endometrioid ; metabolism ; pathology ; Carcinoma, Squamous Cell ; metabolism ; pathology ; Cell Differentiation ; Endometrial Neoplasms ; metabolism ; pathology ; Epithelium ; metabolism ; Esophageal Neoplasms ; metabolism ; pathology ; Esophagus ; metabolism ; Female ; Humans ; Immunohistochemistry ; Lung Neoplasms ; metabolism ; pathology ; Stomach Neoplasms ; metabolism ; pathology

Adenocarcinoma ; metabolism ; Adenoma ; metabolism ; Breast Neoplasms ; metabolism ; Carcinoma, Papillary ; metabolism ; Carcinoma, Small Cell ; metabolism ; Carcinoma, Squamous Cell ; metabolism ; Central Nervous System Neoplasms ; metabolism ; Diagnosis, Differential ; Digestive System Neoplasms ; metabolism ; Female ; Genital Neoplasms, Female ; metabolism ; Humans ; Immunohistochemistry ; Kidney Neoplasms ; metabolism ; Liver Neoplasms ; metabolism ; Lung Neoplasms ; metabolism ; Neuroendocrine Tumors ; metabolism ; Nuclear Proteins ; metabolism ; Pituitary Neoplasms ; metabolism ; Small Cell Lung Carcinoma ; metabolism ; Thyroid Neoplasms ; metabolism ; Thyroid Nuclear Factor 1 ; Transcription Factors ; metabolism

With the improvement of high-throughput genomic technology such as microarray and next-generation sequencing over the last ten to twenty year, we have come to know that the portion of the genome responsible for protein coding constitutes just approximately 1.5%. The remaining 98.5% of the genome not responsible for protein coding have been regarded as 'junk DNA'. More recently, however, 'Encyclopedia of DNA elements project' revealed that most of the junk DNA were transcribed to RNA regardless of being translated into proteins. In addition, many reports support that a lot of these non-coding RNAs play a role in gene regulation. In fact, there are various functioning short non-coding RNAs including rRNA, tRNA, small interfering RNA, and micro RNA. Mechanisms of these RNAs are relatively well-known. Until recently, however, little is known about long non-coding RNAs which consist of 200 nucleotides or more. In this article, we will review the representative long non-coding RNAs which have been reported to be related to gastrointestinal cancers and to play a certain role in its pathogenesis.
Gastrointestinal Neoplasms/*genetics/*metabolism/pathology ; Humans ; Liver Neoplasms/genetics/metabolism/pathology ; RNA, Long Noncoding/genetics/*metabolism

With the improvement of high-throughput genomic technology such as microarray and next-generation sequencing over the last ten to twenty year, we have come to know that the portion of the genome responsible for protein coding constitutes just approximately 1.5%. The remaining 98.5% of the genome not responsible for protein coding have been regarded as 'junk DNA'. More recently, however, 'Encyclopedia of DNA elements project' revealed that most of the junk DNA were transcribed to RNA regardless of being translated into proteins. In addition, many reports support that a lot of these non-coding RNAs play a role in gene regulation. In fact, there are various functioning short non-coding RNAs including rRNA, tRNA, small interfering RNA, and micro RNA. Mechanisms of these RNAs are relatively well-known. Until recently, however, little is known about long non-coding RNAs which consist of 200 nucleotides or more. In this article, we will review the representative long non-coding RNAs which have been reported to be related to gastrointestinal cancers and to play a certain role in its pathogenesis.
Gastrointestinal Neoplasms/*genetics/*metabolism/pathology ; Humans ; Liver Neoplasms/genetics/metabolism/pathology ; RNA, Long Noncoding/genetics/*metabolism

N6-methyladenosine (m6A) is one of the most common epigenetic modifications of eukaryotic mRNAs, which is involved in the regulation of gene expressions and biological processes in a variety of cells with dynamic and reversible methylation processes. In recent years, many studies have shown that m6A methylation modification not only acts on the growth, proliferation, and medullary differentiation of acute myeloid leukemia cells, but also participates in the regulation of the proliferation and apoptosis of other hematological tumor cells such as chronic myeloid leukemia and diffuse large B-cell lymphoma, and it can even weaken the efficacy of anti-hematological tumor immunotherapy and induce immune escape leading to tumor resistance. With the successive development of a variety of m6A methylation-related enzyme inhibitors, it will provide new therapeutic ideas for patients with relapsed and refractory hematological tumors. In this paper, we review the research progress on the mechanism of m6A methylation on the occurrence, development, and tumor immunity of various hematological tumors.
Adenosine/metabolism* ; Epigenesis, Genetic ; Hematologic Neoplasms/genetics* ; Humans ; Methylation ; Neoplasms/metabolism* ; RNA, Messenger/metabolism*