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- Table of Contents
Facts about Secernin-2.
Human | |
---|---|
Gene Name: | SCRN2 |
Uniprot: | Q96FV2 |
Entrez: | 90507 |
Belongs to: |
---|
peptidase C69 family |
secernin 2; secernin-2; Ses2
Mass (kDA):
46.597 kDA
Human | |
---|---|
Location: | 17q21.32 |
Sequence: | 17; NC_000017.11 (47837691..47841292, complement) |
The SCRN2 marker is an antibody with high specificity that can recognize the SCRN2 protein. It has many uses and its validation has been performed on multiple platforms. Boster also offers product credits and recognition to scientists who review products. This recognition is awarded to researchers around the globe. In this article, we'll examine the benefits of the SCRN2 marker and what it can do for your research.
Secernin is a novel protein encoded by the SCRN2 genome. It is believed that it regulates the exocytosis peritoneal mast cells. This protein could serve as a universal indicator for cancer. This protein can be measured to detect and monitor patients with cancer early. We will describe the validation and use of the SCRN2 mark. We thank the American Society of Clinical Oncologists for its funding of this research.
SCRN2 is not only associated with SCRN1, but also contains the FFAT pattern. Many proteins contain the FFAT motif, including SCRN1. It is known that this protein interacts with VAPs, and we have identified it in brain tissues. Here, we discuss the biological significance of the SCRN2 marker in the development of cancer. It is possible SCRN2 may play a role in regulation of cell growth, cell death, or cell proliferation.
Both genotypic as well as phenotypic data was used. The markers were mapped onto the respective chromosomes. The relative positions close to known Sr genes were also indicated. The quantile-quantile graph was used to compare both the p-values in the two datasets. Our results revealed that twelve significant markers had been identified with a cutoff FDR value of 0.05. Based on the consensus maps developed by Cavanagh (et al.), seven of these markers were located in four chromosomes. Ex_c1373_2628597, one of the most important markers, was also found. This marker is likely a novel gene for Ug99 resistance.
The SCRN2 marker is an fusion protein that recognizes the human gene encoding Secernin proteins. It is thought to be involved exocytosis with peritoneal mamm cells. However, its function has not yet been fully characterized. SCRN1 may be a universal marker for cancer, despite its unclear function. SCRN1 measurement is useful in early-stage detection and monitoring of patients with the disease.
The way research is conducted is changing due to increasing data and AI. This presents many new opportunities, but it also raises many questions. The proliferation of data makes it difficult to properly handle and analyze large quantities of data, especially those that are unreliable. For the replication of published research results, trust in the research community is crucial. These trust environments are becoming more common thanks to a growing number reputable research organizations.
Developing trusting relationships with the research community can help create an environment that fosters productive collaborations and spurs action. Partnerships can result in better treatments and interventions for patients. Public engagement relies on the participation of stakeholders as well as a culture of trust and mutual respect. Trustworthy researchers have all the qualities and skills necessary to establish strong relationships with communities. This trust requires a variety of strategies. Here are four ways to increase trust in community research.
Developing trustworthiness among research partners is vital for advancing the research enterprise. In a community-based research partnership, trustworthiness is essential for achieving research goals and upholding the principles of CBPR. For academic researchers to overcome barriers and establish mutually beneficial collaborations, they must build trustworthiness with members of the community. Despite these challenges however, few partnerships have successfully explored how trustworthiness can and should be assessed.
While trust is vital to research partnerships that work, there are many social barriers and obstacles that can hinder trust. Trust issues can include racial/ethnic diversity, inequal access to health care, and even ethical misconduct surrounding Henrietta Lacks’s cells. Trust in research institutions can also cause distrust. When these barriers can be overcome, the research community is more relevant to communities they serve.
Trust is difficult to gain when research is publicly available. Administrators and faculty alike lament the lack of trust in academic research. This situation is not only frustrating for researchers, but it also hampers the dissemination, acceptance, and objectivity of research. Without trust in academic research, the public is less likely to support a university with tax money or to want their children to attend a university.
PMID: 14702039 by Ota T., et al. Complete sequencing and characterization of 21,243 full-length human cDNAs.
PMID: 16625196 by Zody M.C., et al. DNA sequence of human chromosome 17 and analysis of rearrangement in the human lineage.