Recombinant ENPP1 Mouse Protein [HEK 293.] (MAG-3598)

ENPP1 Mouse

MAG-3598

His

HEK 293.

At Room Temperature

ENPP1 Mouse Recombinant produced in HEK cells is a single, glycosylated, polypeptide chain containing 828 amino acids (Lys85-Glu906) and having a molecular mass of 95.2kDa. ENPP1 Mouse is fused to a 6 a.a his tag at C-Terminus and is purified by proprietary chromatographic techniques.

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Filtered White lyophilized (freeze-dried) powder.

The filtered (0.4µm) concentrated protein solution was lyophilized with PBS, PH 7.5.

Store lyophilized protein at -20°C. Aliquot the product after reconstitution to avoid repeated freezing/thawing cycles. Reconstituted protein can be stored at 4°C for a limited period of time.

Greater than 95.0% as determined by SDS-PAGE.

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SDS

Mabioway's products are furnished for LABORATORY RESEARCH USE ONLY. The product may not be used as drugs, agricultural or pesticidal products, food additives or household chemicals.

Ectonucleotide pyrophosphatase/phosphodiesterase family member 1, E-NPP 1, Membrane component chromosome 6 surface marker 1, Phosphodiesterase I/nucleotide pyrophosphatase 1, Plasma-cell membrane glycoprotein PC-1, ENPP1, M6S1, NPPS, PC1, PDNP1, NPP1, PC-1, PCA1, ARHR2, COLED.

KEVKSCKGRC FERTFSNCRC DAACVSLGNC CLDFQETCVE PTHIWTCNKF RCGEKRLSRF VCSCADDCKT HNDCCINYSS VCQDKKSWVE ETCESIDTPE CPAEFESPPT LLFSLDGFRA EYLHTWGGLL PVISKLKNCG TYTKNMRPMY PTKTFPNHYS IVTGLYPESH GIIDNKMYDP KMNASFSLKS KEKFNPLWYK GQPIWVTANH QEVKSGTYFW PGSDVEIDGI LPDIYKVYNG SVPFEERILA VLEWLQLPSH ERPHFYTLYL EEPDSSGHSH GPVSSEVIKA LQKVDRLVGM LMDGLKDLGL DKCLNLILIS DHGMEQGSCK KYVYLNKYLG DVNNVKVVYG PAARLRPTDV PETYYSFNYE ALAKNLSCRE PNQHFRPYLK PFLPKRLHFA KSDRIEPLTF YLDPQWQLAL NPSERKYCGS GFHGSDNLFS NMQALFIGYG PAFKHGAEVD SFENIEVYNL MCDLLGLIPA PNNGSHGSLN HLLKKPIYNP SHPKEEGFLS QCPIKSTSND LGCTCDPWIV PIKDFEKQLN LTTEDVDDIY HMTVPYGRPR ILLKQHHVCL LQQQQFLTGY SLDLLMPLWA SYTFLRNDQF SRDDFSNCLY QDLRIPLSPV HKCSYYKSNS KLSYGFLTPP RLNRVSNHIY SEALLTSNIV PMYQSFQVIW HYLHDTLLQR YAHERNGINV VSGPVFDFDY DGRYDSLEIL KQNSRVIRSQ EILIPTHFFI VLTSCKQLSE TPLECSALES SAYILPHRPD NIESCTHGKR ESSWVEELLT LHRARVTDVE LITGLSFYQD RQESVSELLR LKTHLPIFSQ ED HHHHHH .

Ectonucleotide pyrophosphatase/phosphodiesterase 1 (ENPP1) is an enzyme with multifaceted roles in cellular metabolism, bone mineralization, and insulin signaling. Research utilizing mouse models has been pivotal in elucidating the complex biology of ENPP1 and its implications for various physiological processes and disease states. This study aims to provide a comprehensive exploration of ENPP1 in mouse physiology, shedding light on its diverse functions and potential applications in understanding metabolic health and disease mechanisms. The primary objective of this research is to elucidate the impact of ENPP1 in mouse models on metabolic health. In vivo experiments using genetically modified mice with altered ENPP1 expression or activity will be conducted to investigate how ENPP1 influences glucose homeostasis, insulin sensitivity, and lipid metabolism. Understanding these mechanisms is fundamental for deciphering the role of ENPP1 in metabolic diseases such as diabetes and obesity. The second objective is to assess the clinical relevance of ENPP1 in mouse models of bone health. Mouse models of skeletal disorders will be employed to explore how ENPP1 affects bone mineralization, density, and remodeling. These investigations may provide valuable insights into potential therapeutic strategies targeting ENPP1 in bone-related diseases. The third objective is to explore the broader implications of ENPP1 in mouse physiology, including its effects on vascular health, inflammation, and tissue repair. Research will investigate its roles in vascular calcification, inflammation resolution, and tissue regeneration. Understanding the multifaceted properties of ENPP1 in mouse models may open new avenues for therapeutic interventions in various metabolic and chronic disease contexts. By delving into the diverse functions of ENPP1 in mouse physiology, this research aims to expand our knowledge of its physiological roles and clinical applications. The findings may contribute to the development of targeted interventions for metabolic diseases, bone disorders, and other conditions influenced by ENPP1.