User:CsumbFB/ZXDC

Zinc finger, X-linked, duplicated family member C (ZXDC) is a human CIITA-binding protein involved in the activation of major histocompatibility complex (MHC) class I and II. For binding to occur, ZXDC must form an oligomeric complex with another copy of itself or with ZXDA, a related protein. ZXDC is activated by sumoylation, a post-translational modification.

History:

When Sakaue and colleagues searched for novel transcription factors involved in the development of Xenopus laevis, they discovered ZXDC (ZXD Family Zinc Finger C). This discovery was discovered in a research article that was published in 1998. They found a cDNA clone called "Xfin" that encodes a protein with two zinc finger C2H2 domains.

Later research established the interspecies conservation of the Xfin protein, and the human equivalent was given the name ZXDC. It was discovered that the protein was broadly generated in human tissues and that a number of variables, including hypoxia, estrogen, and cytokines, controlled how the protein was expressed.

Composition:

ZXDC is a protein composed of 455 amino acids in humans, with a molecular weight of approximately 49.9 kDa.

Near its C-terminus, the protein has two C2H2-type zinc finger domains that are likely to be involved in DNA binding and transcriptional control. A flexible linker region that separates the zinc fingers may provide more adaptability in binding to various DNA sequences.

Other domains found in ZXDC include a proline-rich region close to the N-terminus that may be important in protein-protein interactions and a central region that is projected to be intrinsically disordered. ZXDC also contains numerous other features in addition to the zinc fingers. Although the exact purpose of these domains is not yet known, they might assist in mediating interactions with other proteins or controlling the activity of the protein.

ZXDC has mostly been investigated in the context of developmental biology and cell fate determination in animals. Studies in fruit flies, for instance, have demonstrated that protein is crucial for the development of particular cell types, such as the cell precursors of the sensory organs in the peripheral nervous system.

Function:

ZXDC (ZXD Family Zinc Finger C) is a protein-coding gene that controls biological processes such as cell division, proliferation, and apoptosis. This gene produces a protein with two C2H2-type zinc fingers that are a member of the ZXD family.

ZXDC has been linked to the formation of numerous cancer forms and it regulates the advancement of the cell cycle. It is also known to interact with other proteins, including GSK3β, a serine/threonine protein kinase implicated in a number of signaling pathways, and p53, an important tumor suppressor.

By regulating the expression of genes linked to the innate immune response, ZXDC has also been demonstrated to contribute to the regulation of immunological responses. As a result, it is believed that ZXDC could be a possible target for the creation of new remedies for autoimmune and cancerous conditions.

Solubility:

ZXDC's solubility is not well described in the literature and may vary depending on a number of variables, including the protein's expression system, the buffering situation, and the presence of other proteins or chemicals. But studies have shown the effective separation of ZXDC using a variety of techniques, including gel filtration and affinity chromatography, suggesting that the protein is probably soluble in some circumstances. For instance, one study found superior amounts of soluble protein and pure recombinant ZXDC protein generated in Escherichia Coli using immobilized metal affinity chromatography (IMAC).

Role in disease:

Numerous cancers, including breast, lung, and colorectal cancer, have been linked to ZXDC, according to studies. It is also considered to be a possible therapeutic target for autoimmune and cancer conditions. ZXDC abnormality has been linked to cancer progression and an unfavorable prognosis.

In breast cancer, low ZXDC expression has been associated with tumor invasiveness, lymph node metastases, and poor prognosis. ZXDC suppresses the growth and migration of breast cancer cells, acting as a tumor suppressor.

The emergence of a more aggressive form of lung cancer has been correlated with decreased ZXDC expression. Studies have demonstrated that increasing ZXDC expression can prevent tumor development and invasion in lung cancer cells.

In colorectal cancer, the loss of ZXDC expression has been connected to the advancement of the disease stage and lymph node metastasis. In addition, it has been proposed that ZXDC may function as a tumor suppressor by obstructing the Wnt/beta-catenin signaling pathway, which is frequently active in colorectal cancer.

Overall, these results indicate that ZXDC may be a key player in the initiation and development of cancer, and it may also hold interest as a diagnostic or therapeutic target for the treatment of cancer. To completely comprehend the processes underlying ZXDC's activity in cancer and to design specific treatments based on it, more study is necessary.

Fun facts about ZXDC:

ZXDC is significantly conserved between species, showing the significance of this gene for cellular functions.

According to a 2016 study, ZXDC is involved in controlling the circadian clock in cells, which regulates the daily cycles of physiological processes.

While the majority of ZXDC research has concentrated on the genesis and progression of cancer, other disorders like multiple sclerosis and Crohn's disease have also been related.

ZXDC is just one part of a larger family of zinc finger proteins that are crucial for the regulation of genes and cellular functions in a variety of organisms.

Overall:

In conclusion, ZXDC is a complicated protein with a variety of domains and possible uses. The protein's relevance in numerous cellular and developmental processes is indicated by the fact that it is largely preserved across species. According to studies, ZXDC may play a function in controlling immunological responses, cancer formation and progression, and cell proliferation, differentiation, and survival. However, current research is striving to clarify these functions because the precise mechanisms of action of ZXDC and its particular involvement in these processes are still not entirely understood. Additional research on ZXDC may result in the creation of novel diagnostic and therapeutic strategies for a number of disorders as well as a greater comprehension of the basic principles governing cellular regulation.

Future Research:

Future research on ZXDC may concentrate on a number of topics, such as its function in the initiation and progression of cancer, the control of cellular functions, and connections with other proteins.

The mechanisms by which ZXDC affects the function of tumor suppressor proteins like p53 and whether targeting ZXDC could be a useful treatment strategy for some types of cancer are two possible study directions. The potential of ZXDC as a biochemical indicator for cancer diagnosis or prognosis could also be studied.

Given its alleged involvement in these processes, the function of ZXDC in immunological reactions and inflammation may also be of interest. Additional research may clarify the precise processes by which ZXDC controls immune cells and the therapeutic implications of focusing on this protein in immunological-related disorders.

Therefore, further research on ZXDC may clarify the variety of functions it plays in cellular functions and disorders, and may also pave the way for the creation of alternative diagnostic and therapeutic strategies.

External links[edit]


 * ZXDC at NIH NCBI
 * ZXDC at Uniprot
 * ZXDC GeneCard