Cat. No.: 197-0P
Amount: 100 µg
Price:
$110.00
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| Cat. No. 197-0P |
100 µg protein, lyophilized. For reconstitution add 100 µl H2O to get a 1mg/ml solution in TBS. Then aliquot and store at -20°C to -80°C until use. Control proteins should be stored at +4°C when still lyophilized. Do not freeze! |
| Applications |
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| Immunogen | Recombinant protein corresponding to AA 2 to 75 from mouse ZnT3 (UniProt Id: P97441) |
| Recommended dilution | Optimal concentrations should be determined by the end-user. |
| Matching antibodies | 197 002, 197 003, 197 003C3, 197 004, 197 011, 197 011BT, 197 006, 197 003DY2, 197 003DY5 |
| Remarks |
This control protein consists of the recombinant protein (aa 2 - 75 of mouse ZnT 3) that has been used for immunization. It has been tested in preadsorption experiments and blocks efficiently and specifically the corresponding signal in Western blots. The amount of peptide needed for efficient blocking depends on the titer and on the affinity of the antibody to the antigen. |
| Data sheet | 197-0p.pdf |
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The essential micronutrient zinc (Zn2+) plays an important role in many biological processes like growth, development, and reproduction. It is found in the active site of many enzymes, where ionization, polarization or replacement of Zn2+ bound water is involved in catalytic reactions. As a charged ion Zn2+ cannot cross biological membranes by simple diffusion and must be transported by specialized transport mechanisms. Two families of Zn2+ transporters, SLC30 (ZnT, Zn2+ transporter) and SLC39 (ZIP, Zinc (Zn2+)-Iron (Fe2+) permease), function in opposite directions to maintain cellular Zn2+ homeostasis (1).
Ten Zn2+ transporter proteins ZnT1-10 have been described. All of them contain several transmembrane domains and a histidine rich intracellular loop (2).
In the central nervous system Zn2+ plays important roles in synaptic function and plasticity. At synapses Zn2+ is stored in synaptic vesicles by a mechanism depending on the integral membrane protein ZnT3 (3). ZnT3 probably contributes to the prevention of aging-related cognitive loss, because ZnT3 expression levels fall with age and in patients with Alzheimer’s or Parkinson’s disease. Consistent with these results, aged ZnT3-KO mice exhibit deficits in learning and memory (3). ZnT3, along with other ZnT family members, is expressed in several endocrine organs, including the pituitary gland, adrenal glands, and thyroid but is absent in the pancreas (4). This transporter also plays an essential role in reproductive health as some studies have demonstrated ZnT3 expression in the ovary. It was reported that ZnT3 is expressed in mouse oocytes throughout all stages of follicular development, where it likely supports Zn2+ accumulation necessary for oocyte maturation. Disruption of ZnT3 in oocytes leads to impaired zinc storage, potentially compromising fertility (5). Interestingly, while ZnT3 mRNA is expressed in testis, no protein was detectable. This discrepancy between mRNA and protein levels highlights the importance of post-transcriptional regulation and protein stability in determining ZnT3’s functional presence in reproductive tissues (6).